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CN108201450B - Method and device for determining ovulation detection time based on electronic equipment - Google Patents

Method and device for determining ovulation detection time based on electronic equipment Download PDF

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CN108201450B
CN108201450B CN201611184580.XA CN201611184580A CN108201450B CN 108201450 B CN108201450 B CN 108201450B CN 201611184580 A CN201611184580 A CN 201611184580A CN 108201450 B CN108201450 B CN 108201450B
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value
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date
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CN108201450A (en
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白莉莉
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Netease Hangzhou Network Co Ltd
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Netease Hangzhou Network Co Ltd
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    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B10/00Other methods or instruments for diagnosis, e.g. instruments for taking a cell sample, for biopsy, for vaccination diagnosis; Sex determination; Ovulation-period determination; Throat striking implements
    • A61B10/0012Ovulation-period determination

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Abstract

In an embodiment of the present invention, a method for determining ovulation detection time based on an electronic device is provided, including: judging whether the physiological cycle of the user is regular or not; determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not; determining a detection deadline, and taking a time period between the detection start date and the detection deadline as an ovulation detection date; in the scheme, the ovulation detection day is determined according to the first starting day of the physiological cycle with the shortest distance from the current date and the judgment result of whether the physiological cycle is regular, so that the condition that whether the physiological cycle is regular is distinguished, and the fact that the ovulation detection day is determined only by the starting time of the next menstruation is avoided, and therefore the accuracy of determining the ovulation detection day is improved.

Description

Method and device for determining ovulation detection time based on electronic equipment
Technical Field
The embodiment of the invention relates to the technical field of data monitoring, in particular to a method and a device for determining ovulation detection time based on electronic equipment.
Background
This section is intended to provide a background or context to the embodiments of the invention that are recited in the claims. The description herein is not admitted to be prior art by inclusion in this section.
Ovulation occurs once or not during the menstrual cycle, and for different women, the ovulation time varies from individual to individual, and the detection of the ovulation status is an important aid for preparing a woman for pregnancy, and therefore, it is necessary to capture a reliable ovulation detection time.
At present, the following two methods are mainly adopted to determine the ovulation test days, and are used as bases for manually using test paper to detect ovulation in the ovulation test days:
one is as follows: the ovulation period is calculated based on the user's physiological cycle and the time of the beginning of the last menstruation. The ovulatory period of a female is generally around the first 14 days of the next menstruation. Starting from day 1 of the next menstruation, 14 days after or minus 14 days are the ovulation starting days, and the first 5 days and the last 4 days of the ovulation starting days are added together to be called the ovulation period. This approach is very inaccurate for users with irregular menstrual cycles and is prone to missing a true day of ovulation.
The other is as follows: the ovulation start day is the number of days in which the shortest one-cycle days of the next menstruation period minus 18, and the ovulation end day is the number of days in which the longest one-cycle days of the next menstruation period minus 11. This method often unnecessarily extends the detection day, and for users with irregular cycles, even covering all physiological cycles, it cannot be used as a reference for detection.
Disclosure of Invention
The start of both methods depends on the starting time of the next menstruation, and the starting day of the next menstruation is uncertain for users with irregular physiological cycles, so that the ovulation detection day calculated according to the methods is inaccurate or cannot be used as a reference, which is a very annoying process.
To this end, there is a great need for an improved method and apparatus for determining ovulation test time that addresses the low accuracy deficiencies of the prior art.
In this context, embodiments of the present invention are intended to provide a method and apparatus for determining ovulation detection time based on electronic devices.
In a first aspect of an embodiment of the present invention there is provided an electronic device based method of determining ovulation detection time, comprising:
judging whether the physiological cycle of the user is regular or not;
determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not;
determining a detection deadline, and setting a time period between the detection start date and the detection deadline as an ovulation detection date.
In one embodiment, the method according to the above embodiment of the present invention, determining the detection start day according to the first start day and the judgment result of whether the physiological cycle is regular includes:
when the physiological cycle rule is judged, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the physiological cycle is judged to be irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
In some embodiments, the method of any one of the above embodiments of the invention, obtaining a target number of days, comprises:
determining whether the physiological cycle is known;
if so, taking the days of the physiological cycle as the target days;
otherwise, calculating the physiological cycle, and taking the minimum value of the calculated days of the physiological cycle and 28 as the target days.
In some embodiments, the method according to any of the above embodiments of the invention, calculating the physiological cycle, comprises:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
In some embodiments, the method of any of the above embodiments of the invention, determining the detection start day from the target number of days and the first start day, comprises:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
In some embodiments, according to the method of any of the above embodiments of the invention, the first preset number of days is 6 days.
In some embodiments, the method of any of the above embodiments of the invention, determining a detection deadline, comprises:
taking the detection starting day as a starting point and taking a date which is a second preset number of days away from the detection starting day as a detection deadline; or measuring the LH value of luteinizing hormone from the start date of the test, and determining the cutoff date of the test according to the LH value.
In some embodiments, the method according to any of the above embodiments of the invention, determining the detection deadline based on the LH value, comprises:
if the physiological cycle is regular, when all LH values measured from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline; and when the days for measuring the LH values do not reach the third preset days from the detection starting day, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is taken as the detection stopping day, wherein the second LH preset value is larger than the first LH preset value. Wherein detection of ovulation may be stopped when an LH peak above the second LH preset value is detected, indicating that the user will ovulate in a short time.
In some embodiments, the method according to any of the above embodiments of the invention, determining the detection deadline based on the LH value, comprises:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day are less than or equal to a first LH preset value, continuing to perform the step of measuring the LH values from a date which is two days away from the detection starting day by the second preset number of days until an LH peak value is detected, and taking the date on which the LH peak value is detected as the detection deadline when the LH peak value is greater than the second LH preset value, wherein the second LH preset value is greater than the first LH preset value.
In some embodiments, according to the method of any one of the above embodiments of the present invention, if the measured LH value within the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, it is recommended to measure the LH value every first preset interval time until an LH peak value is detected, and the LH peak value is greater than the second LH preset value; if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
In some embodiments, according to the method of any of the above embodiments of the present invention, the first LH preset value is 20-30mIU/ml, preferably the first LH preset value is about 25 mIU/ml; the second LH preset value is 40-50mIU/ml, and preferably the second LH preset value is about 45 mIU/ml; the third preset number of days is 8-12 days, and preferably, the third preset number of days is about 10 days; the first preset interval time is 2-6 hours, preferably, the first preset interval time is 2-4 hours; the second preset interval time is 1-3 hours, and preferably, the second preset interval time is about 2 hours.
In a second aspect of an embodiment of the present invention there is provided an electronic device based method of determining ovulation detection time, comprising:
acquiring physiological information and a physiological detection value of a user;
and determining ovulation detection time according to the physiological information and the physiological detection value.
In one embodiment, the method for determining ovulation detection time according to the physiological information and the physiological detection value according to the above embodiment of the present invention comprises:
judging whether the physiological cycle of the user is regular or not according to the physiological information;
determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining the detection starting day according to the first starting day and the judgment result of whether the physiological cycle is regular or not;
measuring a physiological test value from the test start day, determining a test cutoff day based on the physiological test value, and taking a time period between the test start day and the test cutoff day as an ovulation test day.
In some embodiments, the method according to any of the above embodiments of the present invention, wherein determining the detection start day according to the first start day and the judgment result of whether the physiological cycle is regular includes:
when the physiological cycle rule is judged, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the physiological cycle is judged to be irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
In some embodiments, the method of any one of the above embodiments of the invention, obtaining a target number of days, comprises:
determining whether the physiological cycle is known;
if so, taking the days of the physiological cycle as the target days;
otherwise, calculating the physiological cycle, and taking the minimum value of the calculated days of the physiological cycle and 28 as the target days.
In some embodiments, the method according to any of the above embodiments of the invention, calculating the physiological cycle, comprises:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
In some embodiments, the method of any of the above embodiments of the invention, determining the detection start day from the target number of days and the first start day, comprises:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
In some embodiments, according to the method of any of the above embodiments of the invention, the first preset number of days is 6 days.
In some embodiments, the method according to any of the above embodiments of the invention, determining a detection deadline based on the physiological detection value, comprises:
the cutoff day for the assay was determined from luteinizing hormone LH values.
In some embodiments, the method according to any of the above embodiments of the invention, determining the detection deadline based on an LH value, comprises:
if the physiological cycle is regular, when all LH values measured from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline;
and if the physiological cycle rule is adopted, when the number of days for measuring the LH values does not reach the third preset number of days from the detection starting day, the LH peak value appears in all the measured LH values, and the LH peak value is greater than a second LH preset value, the date for detecting the LH peak value is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
In some embodiments, the method according to any of the above embodiments of the invention, determining the detection deadline based on the LH value, comprises:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day are less than or equal to a first LH preset value, continuing to perform the step of measuring the LH values from a date which is two days away from the detection starting day by the second preset number of days until an LH peak value is detected, and taking the date on which the LH peak value is detected as the detection deadline when the LH peak value is greater than the second LH preset value, wherein the second LH preset value is greater than the first LH preset value.
In some embodiments, according to the method of any one of the above embodiments of the present invention, if the measured LH value within the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, it is recommended to measure the LH value every first preset interval time until an LH peak value is detected, and the LH peak value is greater than the second LH preset value; and if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
In some embodiments, according to the method of any of the above embodiments of the present invention, the first LH preset value is 20-30mIU/ml, preferably the first LH preset value is about 25 mIU/ml; the second LH preset value is 40-50mIU/ml, and preferably the second LH preset value is about 45 mIU/ml; the third preset number of days is 8-12 days, and preferably, the third preset number of days is about 10 days; the first preset interval time is 2-6 hours, preferably, the first preset interval time is 2-4 hours; the second preset interval time is 1-3 hours, and preferably, the second preset interval time is about 2 hours.
In a third aspect of an embodiment of the present invention there is provided an electronic device based apparatus for determining the time of ovulation detection, comprising:
the judging unit is used for judging whether the physiological cycle of the user is regular or not;
the determining unit is used for determining a first starting day of the physiological cycle with the shortest distance from the current date and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not;
the determination unit is also used for determining a detection deadline, and taking a time period between the detection start date and the detection deadline as an ovulation detection date.
In an embodiment, according to the device of the foregoing embodiment of the present invention, the determining unit determines the detection start date according to the first start date and the judgment result of whether the physiological cycle is regular, specifically:
when the judging unit judges the physiological cycle rule, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the judging unit judges that the physiological cycle is irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
In some embodiments, according to the device of any previous embodiment of the present invention, the determining unit is further configured to determine whether the physiological cycle is known;
when the determining unit obtains the target days, the determining unit specifically includes:
if the judging unit judges that the physiological cycle is known, taking the days of the physiological cycle as the target days;
if the judging unit judges that the physiological cycle is unknown, the physiological cycle is calculated, and the minimum value of the number of days of the calculated physiological cycle and 28 is used as the target number of days.
In some embodiments, according to the apparatus of any one of the above embodiments of the present invention, when the determining unit calculates the physiological cycle, specifically:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
In some embodiments, according to the device of any one of the above embodiments of the present invention, the determining unit determines the detection start date according to the target number of days and the first start date, specifically:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
In some embodiments, the device according to any of the above embodiments of the invention, wherein the first preset number of days is 6 days.
In some embodiments, according to the apparatus of any one of the above embodiments of the present invention, the determining unit determines the detection cutoff date specifically as follows:
taking the detection starting day as a starting point and taking a date which is a second preset number of days away from the detection starting day as a detection deadline; or measuring the LH value of luteinizing hormone from the start date of the test, and determining the cutoff date of the test according to the LH value.
In some embodiments, the apparatus according to any of the above embodiments of the present invention, further comprises a detection unit for measuring an LH value from the detection start day;
the determining unit determines the detection cutoff time of day according to the LH value, specifically:
if the physiological cycle is regular, when all LH values measured by the detection unit from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline; and when the days for measuring the LH values do not reach the third preset days from the detection starting day, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is taken as the detection stopping day, wherein the second LH preset value is larger than the first LH preset value.
In some embodiments, the apparatus according to any of the above embodiments of the present invention, further comprises a detection unit for measuring an LH value from the detection start day;
the determining unit determines the detection cutoff time of day according to the LH value, specifically:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day by the detection unit are less than or equal to a first LH preset value, the step of measuring the LH values is continuously executed from a date which is two days away from the second preset number of days from the detection starting day until an LH peak value is detected, and when the LH peak value is greater than the second LH preset value, the date at which the LH peak value is detected is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
In some embodiments, according to the device of any one of the above embodiments of the present invention, if the measured LH value within the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, the detecting unit is suggested to measure the LH value once every first preset interval until an LH peak is detected, and the LH peak is greater than the second LH preset value; if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured by the detection unit at intervals of a second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
In some embodiments, according to the device of any of the above embodiments of the present invention, the first LH preset value is 20-30mIU/ml, preferably the first LH preset value is about 25 mIU/ml; the second LH preset value is 40-50mIU/ml, and preferably the second LH preset value is about 45 mIU/ml; the third preset number of days is 8-12 days, and preferably, the third preset number of days is about 10 days; the first preset interval time is 2-6 hours, preferably, the first preset interval time is 2-4 hours; the second preset interval time is 1-3 hours, and preferably, the second preset interval time is about 2 hours.
In a fourth aspect of an embodiment of the present invention there is provided an electronic device based apparatus for determining the timing of ovulation detection, comprising:
the acquisition unit is used for acquiring physiological information and a physiological detection value of a user;
and the determining unit is used for determining ovulation detection time according to the physiological information and the physiological detection value.
In one embodiment, according to the device of the above embodiment of the present invention, the determining unit includes a judging unit, a detecting unit, a start date determining unit, and a deadline determining unit, wherein:
the judging unit is used for judging whether the physiological cycle of the user is regular or not according to the physiological information;
the starting date determining unit is used for determining a first starting date of the physiological cycle with the shortest distance from the current date and determining the detection starting date according to the first starting date and the judgment result of whether the physiological cycle is regular or not;
the detection unit is used for measuring a physiological detection value from the detection starting date;
and the deadline determining unit is used for determining a detection deadline according to the physiological detection value and taking a time period between the detection start date and the detection deadline as an ovulation detection date.
In some embodiments, according to the device of any one of the above embodiments of the present invention, the starting date determining unit determines the detection starting date according to the first starting date and the judgment result of whether the physiological cycle is regular, specifically:
when the judging unit judges the physiological cycle rule, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the judging unit judges that the physiological cycle is irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
In some embodiments, according to the device of any previous embodiment of the present invention, the determining unit is further configured to determine whether the physiological cycle is known;
when the starting day determining unit obtains the target number of days, the method specifically comprises the following steps:
if the judging unit judges that the physiological cycle is known, taking the days of the physiological cycle as the target days;
if the judging unit judges that the physiological cycle is unknown, the physiological cycle is calculated, and the minimum value of the number of days of the calculated physiological cycle and 28 is used as the target number of days.
In some embodiments, according to the device of any one of the above embodiments of the present invention, when the start date determining unit calculates the physiological cycle, specifically:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
In some embodiments, according to the device of any one of the above embodiments of the present invention, the starting date determining unit determines the detection starting date according to the target number of days and the first starting date, specifically:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
In some embodiments, the device according to any of the above embodiments of the invention, wherein the first preset number of days is 6 days.
In some embodiments, according to the device of any one of the above embodiments of the present invention, the expiration date determination unit determines the detection expiration date according to the physiological detection value, specifically:
the cutoff day for the assay was determined from luteinizing hormone LH values.
In some embodiments, the apparatus according to any of the above embodiments of the present invention, further comprises a detection unit for measuring an LH value from the detection start day;
the cutoff day determining unit determines the detection cutoff day according to the LH value, and specifically comprises the following steps:
if the physiological cycle is regular, when all LH values measured by the detection unit from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline;
if the physiological cycle rule is adopted, when the detecting unit starts from the detection starting day, the number of days for measuring the LH values does not reach the third preset number of days, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is used as the detection deadline, wherein the second LH preset value is larger than the first LH preset value.
In some embodiments, the apparatus according to any of the above embodiments of the present invention, further comprises a detection unit for measuring an LH value from the detection start day;
the cutoff day determining unit determines the detection cutoff day according to the LH value, specifically:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day by the detection unit are less than or equal to a first LH preset value, the step of measuring the LH values is continuously executed from a date which is two days away from the second preset number of days from the detection starting day until an LH peak value is detected, and when the LH peak value is greater than the second LH preset value, the date at which the LH peak value is detected is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
In some embodiments, according to the device of any one of the above embodiments of the present invention, if the LH value measured by the detection unit during the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, the detection unit is suggested to measure the LH value once every first preset interval until an LH peak is detected, and the LH peak is greater than the second LH preset value; if the LH value measured by the detection unit in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the detection unit is recommended to measure the LH value once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
In some embodiments, according to the device of any of the above embodiments of the present invention, the first LH preset value is 20-30mIU/ml, preferably the first LH preset value is about 25 mIU/ml; the second LH preset value is 40-50mIU/ml, and preferably the second LH preset value is about 45 mIU/ml; the third preset number of days is 8-12 days, and preferably, the third preset number of days is about 10 days; the first preset interval time is 2-6 hours, preferably, the first preset interval time is 2-4 hours; the second preset interval time is 1-3 hours, and preferably, the second preset interval time is about 2 hours.
In an embodiment of the present invention, a method for determining ovulation detection time based on an electronic device is provided, including: judging whether the physiological cycle of the user is regular or not; determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not; determining a detection deadline, and taking a time period between the detection start date and the detection deadline as an ovulation detection date; in the scheme, the ovulation detection day is determined according to the first starting day of the physiological cycle with the shortest distance from the current date and the judgment result of whether the physiological cycle is regular, so that the condition that whether the physiological cycle is regular is distinguished, and the fact that the ovulation detection day is determined only by the starting time of the next menstruation is avoided, and therefore the accuracy of determining the ovulation detection day is improved. In addition, the method can be executed by electronic equipment, the detection value can be automatically received by combining with the electronic equipment, the user can realize automatic and accurate calculation only by recording a small amount of physiological parameters, and the method gives a prompt, can reliably ensure the detection of ovulation and provides convenience for the user.
Drawings
The above and other objects, features and advantages of exemplary embodiments of the present invention will become readily apparent from the following detailed description read in conjunction with the accompanying drawings. Several embodiments of the invention are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings and in which:
figure 1A schematically illustrates a scenario for electronic device based determination of ovulation test time, in accordance with an embodiment of the present invention;
figure 1B schematically illustrates another scenario for electronic device based determination of ovulation test time, in accordance with an embodiment of the present invention;
figure 1C schematically illustrates a flow chart of an electronic device based method of determining ovulation detection time, in accordance with an embodiment of the present invention;
figure 1D schematically illustrates an interactive interface diagram of recommended ovulation test times, in accordance with an embodiment of the present invention;
figure 1E schematically illustrates an interface diagram recommending a particular test period within a recommended ovulation test period, in accordance with an embodiment of the present invention;
figure 2 schematically illustrates another flow diagram of an electronic device based method of determining ovulation detection time, in accordance with an embodiment of the present invention;
figure 3 schematically shows a schematic view of an electronic device based ovulation detection time determining apparatus according to an embodiment of the present invention;
figure 4 schematically illustrates another schematic diagram of an electronic device based ovulation detection time determining apparatus according to an embodiment of the present invention;
figure 5 schematically illustrates another schematic diagram of an electronic device based ovulation detection time determining apparatus according to an embodiment of the present invention;
figure 6 schematically illustrates another schematic diagram of an electronic device based ovulation detection time determination apparatus according to an embodiment of the present invention;
in the drawings, the same or corresponding reference numerals indicate the same or corresponding parts.
Detailed Description
The principles and spirit of the present invention will be described with reference to a number of exemplary embodiments. It is understood that these embodiments are given solely for the purpose of enabling those skilled in the art to better understand and to practice the invention, and are not intended to limit the scope of the invention in any way. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.
As will be appreciated by one skilled in the art, embodiments of the present invention may be embodied as a system, apparatus, device, method, or computer program product. Accordingly, the present disclosure may be embodied in the form of: entirely hardware, entirely software (including firmware, resident software, micro-code, etc.), or a combination of hardware and software.
According to an embodiment of the present invention, a method and apparatus for electronic based determination of ovulation detection time is presented.
Technical terms proposed in the embodiments of the present invention are briefly described below.
LH (Luteinizing Hormone), is secreted by adenohypophysis basophils. LH acts synergistically with FSH (folliculting Hormone) to maintain the menstrual cycle of the ovary, leading to ovulation and luteinization;
ovulation: the mature follicle is obviously protruded from the surface of the ovary to a certain stage, the internal pressure is increased along with the surge of the follicular fluid, the protruded part of the ovarian tissue is thinner and thinner, and finally the ovarian follicle is ruptured, and the secondary oocyte, the zona pellucida at the periphery of the secondary oocyte and the radioactive crown are discharged out of the ovary along with the follicular fluid, and the formation is called ovulation.
Best day of detection of ovulatory period: the optimal day of ovulation within a cycle may be 5 consecutive days during which the appearance of an LH peak is most readily observed.
In this document, any number of elements in the drawings is by way of example and not by way of limitation, and any nomenclature is used solely for differentiation and not by way of limitation.
The principles and spirit of the present invention are explained in detail below with reference to several representative embodiments of the invention.
Summary of The Invention
The inventor finds that different algorithms can be executed for different types of users when determining the ovulation test day, for example, the users are distinguished according to whether the physiological cycles are regular, the first start day of the physiological cycle, which is the shortest from the current date, is determined, for example, the current time is 2016, 12 and 13, the physiological cycle, which is the closest to the current time and occurs, is 2016, 11, 20 and 2016, 11, 27, the test start day is determined according to the determined first start day of the physiological cycle and the judgment result of whether the physiological cycle is regular, the test deadline is determined after the test start day, and the time period between the test start day and the test deadline is taken as the ovulation test day. On any of the days of ovulation testing, at least one test is recommended.
Having described the general principles of the invention, various non-limiting embodiments of the invention are described in detail below.
Application scene overview
For example, if the current time is 2016, 12 and 13, and the physiological cycle occurring most recently from the current time is 2016, 11 and 20 days to 2016, 11 and 27 days, the first start date of the physiological cycle that is the shortest from the current date is 2016, 11 and 20 days, it is determined whether the physiological cycle of the user is regular, the detection start date determined from the determination result of whether the physiological cycle of the user is regular together with 2016, 11 and 20 days is 2016, 12 and 8 days, and the detection cutoff date is determined, for example, if the detection cutoff date is 2016, 12 and 15 days, the time period between 2016, 8 days to 2016, 12 and 15 days is taken as the ovulation detection date of the user.
For an electronic device, the following scenarios are enumerated:
in a first scenario, as shown in fig. 1A, a detection device and a server may be included. The detection device can measure the physiological detection value and receive the physiological information input by the user. The detection equipment transmits the received physiological information and the physiological detection value measured by the detection equipment to the server, and the server determines the ovulation detection date and outputs the ovulation detection date information and the ovulation detection time information to the user through the detection equipment.
In a second scenario, a detection device may be included. The detection device can measure the physiological detection value and receive the physiological information input by the user. The detection equipment determines the ovulation detection day based on the received physiological information and the physiological detection value obtained by self detection, and outputs the ovulation detection day and the detection time to the user.
In a third scenario, as shown in fig. 1B, a user terminal, a detection device, and a server may be included. The user terminal receives the physiological information input by the user, and the detection equipment can measure the physiological detection value. The server receives physiological information from the user terminal and a physiological detection value from the detection equipment, determines an ovulation detection day, sends ovulation detection day information and detection time information to the user terminal, and outputs the ovulation detection day information and the detection time information to a user through the user terminal.
In a fourth scenario, a user terminal and a detection device may be included. The user terminal receives the physiological information input by the user, and the detection equipment can measure the physiological detection value. And the user terminal receives the physiological detection value from the detection equipment, determines the ovulation detection date and outputs ovulation detection date information and detection time information to a user.
That is to say, the ovulation time determination method provided by the embodiment of the present invention may be implemented by a server on the network side, may also be implemented by the detection device, may also be implemented by the user terminal, and even may be implemented partially by the server, partially by the detection device, and partially by the user terminal, which is not limited in any way. The electronic devices such as the detection device, the server and the user terminal can be in communication connection through a communication network, and the network can be a local area network, a wide area network and the like. The user terminal and the detection device may also communicate using short-range communication techniques. The server may be any server device capable of supporting the corresponding test strip test.
The above scenarios are covered by the embodiments of the present invention.
Exemplary method
A method for electronic device based determination of ovulation detection time according to an exemplary embodiment of the present invention is described below with reference to fig. 1C in conjunction with the above description and the schematic views of fig. 1A and 1B. It should be noted that the above application scenarios are merely illustrated for the convenience of understanding the spirit and principles of the present invention, and the embodiments of the present invention are not limited in this respect. Rather, embodiments of the present invention may be applied to any scenario where applicable.
Referring to fig. 1C, in an embodiment of the invention, a method 10 for determining ovulation detection time based on an electronic device is provided, including:
step 100: judging whether the physiological cycle of the user is regular or not;
step 110: determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not;
step 120: determining a detection deadline, and setting a time period between the detection start date and the detection deadline as an ovulation detection date.
In the embodiment of the present invention, when determining the detection start date according to the first start date and the judgment result of whether the physiological cycle is regular, optionally, the following method may be adopted:
when the physiological cycle rule is judged, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the physiological cycle is judged to be irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
That is, if the physiological cycle is regular, the detection start day is determined by determining the detection start day according to the target number of days and the first start day, and if the physiological cycle is irregular, the detection start day is directly determined as the date which is located after the first start day and is a first preset number of days away from the first start day.
In the embodiment of the present invention, when the target days are obtained, optionally, the following manner may be adopted:
determining whether the physiological cycle is known;
if so, taking the days of the physiological cycle as the target days;
otherwise, calculating the physiological cycle, and taking the minimum value of the calculated days of the physiological cycle and 28 as the target days.
In the embodiment of the invention, if the user inputs the own physiological cycle, the physiological cycle can be judged to be known, if the user does not input the own physiological cycle but inputs the starting date and the ending date of each physiological cycle, the physiological cycle can be judged to be unknown, the physiological cycle needs to be calculated, the number of days of the calculated physiological cycle is compared with 28, and the minimum value obtained by comparison is taken as the target number of days.
For example, if the user inputs that the physiological cycle is 30 days, the physiological cycle is determined to be known, and the target number of days is directly 30; if the user does not input the specific duration of the physiological cycle, but inputs the start date and the end date of the physiological cycle, it is determined that the physiological cycle is unknown, the current time is 2016, 12, and 13 days, the start date of the physiological cycle of 2016, 11, and 2 days, and the end date is 2016, 11, and 8 days, the start date of the physiological cycle of 2016, 10, and 3 days, and the end date is 2016, 10, and 10 days, it is necessary to calculate the time period between 2016, 10, and 3 days, and 2016, and 11, and 2 days, and compare the time period between 2016, 3 days, and 2 days, 10, and 2016, 11, and 2 days, with 30 days and 28 days, and take the minimum value of 28 days as the target number of days.
In the embodiment of the present invention, when the physiological cycle is calculated, optionally, the following method may be adopted:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
For example, when the current time is 2016, 12 and 13 days, the physiological cycle for 2016, 11 and 11 months is 2016, 2 days to 8 days, and the physiological cycle for 2016, 10 months is 2016, 3 days to 10 days, 10 months and 10 days, respectively, the physiological cycle is 30 days between 2016, 3 days to 2 days, 11 months and 10 months.
In the embodiment of the present invention, when determining the detection start date according to the target number of days and the first start date, optionally, the following manner may be adopted:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
Wherein optionally the relation between the target number of days and the corresponding reference number of days is as shown in table 1.
TABLE 1 relationship between target days and reference days
Figure BDA0001186080380000201
Figure BDA0001186080380000211
For example, when the target number of days is 21 days, the reference number of days is 6 days, i.e., a date of 6 days from the first start date onward is taken as the detection start date; when the target day is 34 days, the reference day is 17 days, and a day counting 17 days from the first start day onward is taken as the detection start day. As can be seen from the above table, when the target days are increasing, the reference days are also increasing gradually in the overall trend, and the same reference days may correspond to more than 1 target days, such as 6 days when the target days are 21 days and 22 days, but the reference days are increasing gradually with the increase of the target days in the overall trend, i.e., the reference days are positively correlated with the target days.
Table 1 is merely an example of the correspondence relationship between the target days and the reference days, and is not limited thereto in practical applications, and will not be described in detail here. The correspondence between the target number of days and the reference number of days may be stored in the electronic device, and the correspondence is invoked for determining the detection start day during calculation.
In an embodiment of the present invention, optionally, the first preset number of days is 6 days.
In the embodiment of the present invention, when determining the detection deadline, optionally, the following manner may be adopted:
taking the detection starting day as a starting point and taking a date which is a second preset number of days away from the detection starting day as a detection deadline; or measuring LH value from the detection starting date, and determining the detection deadline according to the LH value.
In the embodiment of the present invention, the detection cutoff time is determined according to the LH value, and optionally, the following manner may be adopted:
if the physiological cycle is regular, when all LH values measured from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline; and when the days for measuring the LH values do not reach the third preset days from the detection starting day, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is taken as the detection stopping day, wherein the second LH preset value is larger than the first LH preset value.
That is, if the circadian cycle is regular, the determination of the detection deadline has two ways, if all the measured LH values from the detection start date are less than the first LH preset value, in which case the detection is stopped if the number of measured days has reached the third preset number of days, if the measured LH values from the detection start date have a LH peak when the third preset number of days has not been reached, and the LH peak is greater than the second LH preset value, in which case the date on which the LH peak is detected is taken as the detection deadline.
For example, 1/11/2016 is a detection start day, 7/the third preset days are days, the measurement of the LH value is started from 1/11/2016, and if 7/7 consecutive days are measured, the measurement of the LH value is stopped from 8 th day when the measured LH values are all smaller than the first LH preset value; if the LH peak value occurs after continuously measuring for 5 days and is greater than the second LH preset value, in this case, although the measured days do not reach the third preset days of 7 days, the measurement of the LH value is still stopped, and 2016, 11, and 5 days is taken as a detection deadline.
In the foregoing, how to determine the detection deadline according to the LH value when the physiological cycle is regular is described, in practical applications, there is also a case that the physiological cycle is irregular, and in this case, when the detection deadline is determined according to the LH value, optionally, the following manner may be adopted:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day are less than or equal to a first LH preset value, continuing to perform the step of measuring the LH values from a date which is two days away from the detection starting day by the second preset number of days until an LH peak value is detected, and taking the date on which the LH peak value is detected as the detection deadline when the LH peak value is greater than the second LH preset value, wherein the second LH preset value is greater than the first LH preset value.
For example, if 1/2016 is a detection start day, 5 days are preset second days, the LH value is measured from 1/2016, and if 5 days are continuously measured, the measured LH values are all smaller than the first LH preset value, the measurement of the LH values is stopped for the next two days, that is, no LH value is measured for 6/2016 and 7/2016, 11/2016, and the LH value is continuously measured from 8/2016, and if 5 days are continuously measured, the measured LH values are still smaller than the first LH preset value, the measurement of the LH values is continuously stopped for the next two days, that is, no LH value is measured for 13/2016 and 11/14/2016, and the LH values are continuously measured from 15/2016, and so on, until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, the date on which the LH peak value is detected is taken as the detection cutoff day.
In the embodiment of the invention, in order to accurately obtain the ovulation day, the measurement frequency in each day can be increased, so that optionally, if the LH value measured in the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, it is recommended to measure the LH value once every first preset interval time until the LH peak value is detected, and the LH peak value is greater than the second LH preset value; and if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
In the embodiment of the present invention, optionally, the first LH preset value is 20 to 30mIU/ml, the second LH preset value is 40 to 50mIU/ml, the third preset number of days is 8 to 12 days, the first preset interval time is 2 to 6 hours, and the second preset interval time is 1 to 3 hours.
In the scheme, the ovulation detection day is determined according to the first starting day of the physiological cycle with the shortest distance from the current date and the judgment result of whether the physiological cycle is regular, so that the condition that whether the physiological cycle is regular is distinguished, and the fact that the ovulation detection day is determined only by the starting time of the next menstruation is avoided, and therefore the accuracy of determining the ovulation detection day is improved.
In embodiments of the invention, optionally, the ovulation test day and/or the recommended test frequency/amount for the ovulation test day is provided to the user. Optionally, a graphical interaction is provided to the user.
Fig. 1D is a schematic diagram of an embodiment of an interactive interface of an executive body of the method 10 for inputting physiological information of a user and outputting ovulation test time, wherein the user inputs physiological information through selecting yes or no options of "start period" and "end period" at corresponding times on the interactive interface, specific time of menstruation is obtained, such as 6/2016 to 6/10/2016, and time of the same room can be further recorded, and the executive body of the method 10 displays "suggested LH test" time according to the information input by the user: year 2016, 6/19 to year 2016, 6/23.
Further, the executing subject of the method 10 may also recommend a specific detection time at the date of suggesting LH detection according to the physiological detection value, as shown in fig. 1E, and the recommended specific detection time period is 10:00-14:00, 14:00-18:00, 18:00-20: 00.
Referring to fig. 2, in an embodiment of the present invention, there is provided an electronic-based method 20 for determining ovulation detection time, comprising:
step 200: acquiring physiological information and a physiological detection value of a user;
step 210: and determining ovulation detection time according to the physiological information and the physiological detection value.
In the embodiment of the present invention, the physiological information may include at least one of information on whether a physiological cycle is regular, information on a duration of the physiological cycle, information on a start date of the physiological cycle, and information on an end date of the physiological cycle. Of course, other information may also be included and will not be described in detail herein.
For example, the execution subject of the method 20 is an electronic device, which presents the user with options of regular and irregular physiological cycles, and can obtain information about whether the physiological cycle of the user is regular based on the selection of the user; the electronic equipment presents an input interface or an option selection interface of the physiological cycle duration to a user, and acquires information of the physiological cycle duration of the user based on the selection of the user on days or the filling of the days; the electronic equipment can acquire the information of the initial date of the physiological cycle of the user based on the selection of whether the menstruation input by the user starts on a certain day; the electronic device may obtain information of the expiration date of the physiological cycle of the user based on a selection of whether menstruation input by the user on a certain day is ended. Or the electronic equipment acquires the information whether the physiological cycle is regular and/or the information of the physiological cycle duration based on the physiological cycle start date and the physiological cycle end date input by the user. Fig. 1D is a schematic diagram of an interactive interface of the electronic device for inputting physiological information of a user and outputting ovulation test time, where the user inputs physiological information by selecting "yes" or "no" from "start of menstrual period" and "end of menstrual period" options at corresponding times on the interactive interface, so as to obtain specific time of menstrual period, such as 6/2016 to 10/6/2016, and further record the time of the same room, and then the electronic device displays "suggested LH test" time according to the information input by the user: year 2016, 6/19 to year 2016, 6/23.
Further, the electronic device may recommend specific detection time periods on the date where the LH detection is suggested, as shown in fig. 1E, the recommended specific detection time periods are 10:00-14:00, 14:00-18:00, and 18:00-20: 00.
In the embodiment of the present invention, when determining the ovulation detection time according to the physiological information and the physiological detection value, optionally, the following method may be adopted:
judging whether the physiological cycle of the user is regular or not according to the physiological information;
determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining the detection starting day according to the first starting day and the judgment result of whether the physiological cycle is regular or not;
and measuring a physiological detection value from the detection starting day, determining a detection cutoff day according to the physiological detection value, and taking the time period between the detection starting day and the detection cutoff day as ovulation detection time.
In the embodiment of the present invention, when determining the detection start date according to the first start date and the judgment result of whether the physiological cycle is regular, optionally, the following method may be adopted:
when the physiological cycle rule is judged, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the physiological cycle is judged to be irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
That is, if the physiological cycle is regular, the detection start day is determined by determining the detection start day according to the target number of days and the first start day, and if the physiological cycle is irregular, the detection start day is directly determined as the date which is located after the first start day and is a first preset number of days away from the first start day.
In the embodiment of the present invention, when the target number of days is obtained, optionally, whether the physiological cycle is known or not may be determined in the following manner;
if so, taking the days of the physiological cycle as the target days;
otherwise, calculating the physiological cycle, and taking the minimum value of the calculated days of the physiological cycle and 28 as the target days.
In the embodiment of the invention, if the user inputs the own physiological cycle, the physiological cycle can be judged to be known, if the user does not input the own physiological cycle but inputs the starting date and the ending date of each physiological cycle, the physiological cycle is judged to be unknown, the physiological cycle needs to be calculated, the number of days of the calculated physiological cycle is compared with 28, and the minimum value obtained by comparison is taken as the target number of days.
For example, if the user inputs that the physiological cycle is 30 days, the physiological cycle is determined to be known, and the target number of days is directly 30; if the user does not input the specific duration of the physiological cycle, but inputs the start date and the end date of the physiological cycle, it is determined that the physiological cycle is unknown, the current time is 2016, 12, and 13 days, the start date of the physiological cycle of 2016, 11, and 2 days, and the end date is 2016, 11, and 8 days, the start date of the physiological cycle of 2016, 10, and 3 days, and the end date is 2016, 10, and 10 days, it is necessary to calculate the time period between 2016, 10, and 3 days, and 2016, and 11, and 2 days, and compare the time period between 2016, 3 days, and 2 days, 10, and 2016, 11, and 2 days, with 30 days and 28 days, and take the minimum value of 28 days as the target number of days.
In the embodiment of the present invention, when the physiological cycle is calculated, optionally, the following method may be adopted:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
For example, when the current time is 2016, 12 and 13 days, the physiological cycle for 2016, 11 and 11 months is 2016, 2 days to 8 days, and the physiological cycle for 2016, 10 months is 2016, 3 days to 10 days, 10 months and 10 days, respectively, the physiological cycle is 30 days between 2016, 3 days to 2 days, 11 months and 10 months.
In the embodiment of the present invention, when determining the detection start date according to the target number of days and the first start date, optionally, the following manner may be adopted:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
Wherein optionally the relation between the target number of days and the corresponding reference number of days is as shown in table 1.
For example, when the target number of days is 21 days, the reference number of days is 6 days, i.e., a date of 6 days from the first start date onward is taken as the detection start date; when the target day is 34 days, the reference day is 17 days, and a day counting 17 days from the first start day onward is taken as the detection start day. As can be seen from table 1, when the target days are increasing, the reference days are also increasing gradually in the overall trend, the same reference day may correspond to more than 1 target day, such as 6 days when the target days are 21 days and 22 days, but the reference days are increasing gradually with the target days in the overall trend, i.e. the reference days are positively correlated with the target days.
Table 1 is merely an example of the correspondence relationship between the target days and the reference days, and is not limited thereto in practical applications, and will not be described in detail here. The correspondence between the target number of days and the reference number of days may be stored in the electronic device, and the correspondence is invoked for determining the detection start day during calculation.
In an embodiment of the present invention, optionally, the first preset number of days is 6 days.
In an embodiment of the present invention, optionally, determining a detection deadline according to the physiological detection value includes:
determining the detection deadline based on the LH value.
In this embodiment of the present invention, optionally, determining the detection deadline according to the LH value includes:
if the physiological cycle is regular, when all LH values measured from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline;
and if the physiological cycle rule is adopted, when the number of days for measuring the LH values does not reach the third preset number of days from the detection starting day, the LH peak value appears in all the measured LH values, and the LH peak value is greater than a second LH preset value, the date for detecting the LH peak value is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
That is, if the circadian cycle is regular, the determination of the detection deadline has two ways, if all the measured LH values from the detection start date are less than the first LH preset value, in which case the detection is stopped if the number of measured days has reached the third preset number of days, if the measured LH values from the detection start date have a LH peak when the third preset number of days has not been reached, and the LH peak is greater than the second LH preset value, in which case the date on which the LH peak is detected is taken as the detection deadline.
For example, 1/11/2016 is a detection start day, 7/the third preset days are days, the measurement of the LH value is started from 1/11/2016, and if 7/7 consecutive days are measured, the measurement of the LH value is stopped from 8 th day when the measured LH values are all smaller than the first LH preset value; if the LH peak value occurs after continuously measuring for 5 days and is greater than the second LH preset value, in this case, although the measured days do not reach the third preset days of 7 days, the measurement of the LH value is still stopped, and 2016, 11, and 5 days is taken as a detection deadline.
In the foregoing, how to determine the detection deadline according to the LH value when the physiological cycle is regular is described, in practical applications, there is also a case that the physiological cycle is irregular, and in this case, when the detection deadline is determined according to the LH value, optionally, the following manner may be adopted:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day are less than or equal to a first LH preset value, continuing to perform the step of measuring the LH values from a date which is two days away from the detection starting day by the second preset number of days until an LH peak value is detected, and taking the date on which the LH peak value is detected as the detection deadline when the LH peak value is greater than the second LH preset value, wherein the second LH preset value is greater than the first LH preset value.
For example, if 1/2016 is a detection start day, 5 days are preset second days, the LH value is measured from 1/2016, and if 5 days are continuously measured, the measured LH values are all smaller than the first LH preset value, the LH values are stopped to be measured for the next two days, that is, no LH value is measured for 6/2016 and 7/2016 and the LH value is continuously measured from 8/2016, and if 5 days are continuously measured, the measured LH values are still smaller than the first LH preset value, the LH values are stopped to be measured for the next two days, that is, no LH value is measured for 13/2016 and 14/2016, the LH value is continuously measured from 15/2016, and so on, until the LH peak value is detected, and the LH peak value is larger than the second preset LH value, the date on which the LH peak value is detected is taken as the detection cutoff day.
In the embodiment of the invention, in order to accurately obtain the ovulation day, the measurement frequency in each day can be increased, so that optionally, if the LH value measured in the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, it is recommended to measure the LH value once every first preset interval time until the LH peak value is detected, and the LH peak value is greater than the second LH preset value; and if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
In the embodiment of the present invention, optionally, the first LH preset value is 20 to 30mIU/ml, the second LH preset value is 40 to 50mIU/ml, the third preset number of days is 8 to 12 days, the first preset interval time is 2 to 6 hours, and the second preset interval time is 1 to 3 hours.
In a specific embodiment, determining the detection deadline based on the physiological detection value may include the following:
in a recommended period of a third preset number of days (for example, 5 days) after the detection start day, if an LH peak is detected and the peak value is greater than 45mIU/ml, which indicates that ovulation may occur, the date when the peak value is detected is taken as a detection deadline, the recommendation in the current physiological period is stopped, and the detection date prompt of LH is updated to the next period.
After the lapse of a recommended period of a third preset number of days (e.g., 5 days) after the start date of the test, if all measured LH values are < 25 mIU/ml:
for a user with a regular physiological cycle: continuous detection for a third preset number of days, for example, 5 days, is continuously recommended. If the peak value of LH is detected within 5 days and the peak value is more than 45mIU/ml, which indicates that ovulation possibly occurs, the date of detecting the peak value is taken as a detection deadline, the recommendation in the current physiological cycle is stopped, and meanwhile, the detection date of LH is reminded to update to the next cycle; if the peak value does not appear within 5 days, taking the 5 th day as a detection deadline, and stopping the detection recommendation of the current physiological cycle;
for users with irregular physiological cycles: after 2 days, continuous detection is continuously recommended for a third preset number of days, for example, 5 days. And by analogy, the recommendation in the current physiological cycle is stopped until the LH peak is detected, and the recommendation in the next physiological cycle is entered.
In the detection, if the detected value of a user on a certain day is more than or equal to 25mIU/mL and less than or equal to 45mIU/mL, the detection is prompted to be performed once every 2-4 hours, and the detection time is updated synchronously; if the user detects that the value is more than 45mIU/mL at a certain time but the peak value does not appear yet, the detection is prompted to be performed every 2 hours in the future.
In this scheme, the ovulation test day is determined based on the physiological information and the physiological test value, avoiding the need to rely solely on the starting time of the next menstruation, thus improving the accuracy of determining the ovulation test day.
Exemplary device
Having described the method and apparatus of an exemplary embodiment of the invention, next, an apparatus for determining ovulation detection time based on an electronic device according to another exemplary embodiment of the invention is described.
Referring to fig. 3, in an embodiment of the present invention, an apparatus 30 for determining ovulation detection time based on an electronic device is provided, including:
a judging unit 300, configured to judge whether a physiological cycle of a user is regular;
a determining unit 310, configured to determine a first starting date of the physiological cycle that is the shortest distance from the current date, and determine a detection starting date according to the first starting date and a determination result of whether the physiological cycle is regular;
the determination unit 310 is further configured to determine a detection deadline, and to use a time period between the detection start date and the detection deadline as an ovulation detection date.
In this embodiment of the present invention, optionally, the determining unit 310 determines the detection start date according to the first start date and the judgment result of whether the physiological cycle is regular, specifically:
when the judging unit 300 judges the physiological cycle rule, acquiring a target number of days, and determining the detection start date according to the target number of days and the first start date;
when the determination unit 300 determines that the physiological cycle is irregular, a date which is located after the first start date and is a first preset number of days from the first start date is used as the detection start date.
That is, if the physiological cycle is regular, the detection start day is determined by determining the detection start day according to the target number of days and the first start day, and if the physiological cycle is irregular, the detection start day is directly determined as the date which is located after the first start day and is a first preset number of days away from the first start day.
In this embodiment of the present invention, further, the determining unit 300 is further configured to determine whether the physiological cycle is known;
when the determining unit 310 obtains the target number of days, specifically:
if the judging unit 300 judges that the physiological cycle is known, taking the number of days of the physiological cycle as the target number of days;
if the determination unit 300 determines that the physiological cycle is unknown, the physiological cycle is calculated, and the minimum value between the number of days of the calculated physiological cycle and 28 is used as the target number of days.
In the embodiment of the present invention, if the user inputs his/her physiological cycle, the determining unit 300 may determine that the physiological cycle is known, and if the user does not input his/her physiological cycle, but inputs the start date and the end date of each physiological cycle, the determining unit 300 determines that the physiological cycle is unknown, the determining unit 310 needs to calculate the physiological cycle, and compares the number of days of the calculated physiological cycle with 28, and uses the minimum value obtained by the comparison as the target number of days.
For example, if the user inputs a physiological cycle of 30 days, the determination unit 300 determines that the physiological cycle is known, and directly takes 30 as the target number of days; if the user does not input a specific duration of the physiological cycle, but inputs the start date and the end date of the physiological cycle, the determination unit 300 determines that the physiological cycle is unknown, the current time is 2016, 12, and 13 days, the start date of the physiological cycle of 2016, 11, and 2 days, and the end date is 2016, 11, and 8 days, respectively, for the physiological cycle of 2016, 10, and 10 days, respectively, the start date of the physiological cycle of 2016, 10, and the end date is 2016, 10, and 10 days, respectively, for the physiological cycle of 2016, 10, and 10 days, respectively, the time period between 2016, 3, and 11, and 2 days, 10, and 2016, 3, and 2016, 10, and 2016, and 10 days, respectively, needs to be calculated, and the time period between 30 days and 28 days, respectively, between 2016, 3, and 11, and 2 days, is compared, and the minimum.
In an embodiment of the present invention, optionally, when the determining unit 310 calculates the physiological cycle, specifically:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
For example, when the current time is 2016, 12 and 13 days, the physiological cycle for 2016, 11 and 11 months is 2016, 2 days to 8 days, and the physiological cycle for 2016, 10 months is 2016, 3 days to 10 days, 10 months and 10 days, respectively, the physiological cycle is 30 days between 2016, 3 days to 2 days, 11 months and 10 months.
In this embodiment of the present invention, the determining unit 310 determines the detection start time according to the target number of days and the first start day, specifically:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
Wherein optionally the relation between the target number of days and the corresponding reference number of days is as shown in table 1.
For example, when the target number of days is 21 days, the reference number of days is 6 days, i.e., a date of 6 days from the first start date onward is taken as the detection start date; when the target day is 34 days, the reference day is 17 days, and a day counting 17 days from the first start day onward is taken as the detection start day. As can be seen from the above table, when the target days are increasing, the reference days are also increasing gradually in the overall trend, and the same reference days may correspond to more than 1 target days, such as 6 days when the target days are 21 days and 22 days, but the reference days are increasing gradually with the increase of the target days in the overall trend, i.e., the reference days are positively correlated with the target days.
Table 1 is merely an example of the correspondence relationship between the target days and the reference days, and is not limited thereto in practical applications, and will not be described in detail here. The correspondence between the target number of days and the reference number of days may be stored in the electronic device, and the correspondence is invoked for determining the detection start day during calculation.
In an embodiment of the present invention, optionally, the first preset number of days is 6 days.
In this embodiment of the present invention, the determining unit 310 determines the detection deadline specifically as follows:
taking the detection starting day as a starting point and taking a date which is a second preset number of days away from the detection starting day as a detection deadline; or measuring the LH value of luteinizing hormone from the start date of the test, and determining the cutoff date of the test according to the LH value.
In this embodiment of the present invention, further, the apparatus further includes a detecting unit 320, configured to measure an LH value from the detection start date;
the determining unit 310 determines the detection cutoff time of day according to the LH value, specifically:
if the physiological cycle is regular, when all the LH values measured by the detecting unit 320 from the detection start date are less than or equal to the first LH preset value, taking a date which is a third preset number of days apart from the detection start date as the detection deadline; and when the days for measuring the LH values do not reach the third preset days from the detection starting day, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is taken as the detection stopping day, wherein the second LH preset value is larger than the first LH preset value.
That is, if the circadian cycle is regular, there are two ways to determine the detection deadline, if all the LH values measured by the detection unit 320 are smaller than the first LH preset value if the measurement starts from the detection start day, in which case the detection unit 320 stops the detection if the number of measured days has reached the third preset number of days, and if the measurement starts from the detection start day, the LH value measured by the detection unit 320 has a LH peak value when the third preset number of days has not been reached, and the LH peak value is larger than the second LH preset value, in which case the determination unit 310 takes the date on which the LH peak value is detected as the detection deadline.
For example, when 1/11/2016 is a detection start day, the third preset number of days is 7 days, the detection unit 320 starts measuring the LH value from 1/11/2016, and stops measuring the LH value from 8 days if the measured LH values are less than the first LH preset value after 7 days are continuously measured; if the LH peak value occurs after continuously measuring for 5 days and is greater than the second LH preset value, in this case, although the measured days do not reach the third preset days of 7 days, the measurement of the LH value is still stopped, and 2016, 11, and 5 days is taken as a detection deadline.
In the foregoing, when the physiological cycle is regular, how to determine the detection deadline according to the LH value also has an irregular physiological cycle in practical applications. Further, the apparatus further comprises a detecting unit 320 for measuring an LH value from the detection start day;
the determining unit 310 determines the detection cutoff time of day according to the LH value, specifically:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection start date are less than or equal to a first LH preset value, the detecting unit 320 continues to perform the step of measuring LH values from a date spaced by two days from the detection start date until an LH peak value is detected, and when the LH peak value is greater than the second LH preset value, the date at which the LH peak value is detected is taken as the detection cutoff date, wherein the second LH preset value is greater than the first LH preset value.
For example, if 1/11/2016 is a detection start day, the second preset number of days is 5 days, the detection unit 320 starts measuring the LH value from 1/11/2016, and if 5 days are continuously measured, and the measured LH values are all smaller than the first LH preset value, the measurement of the LH values is stopped for the next two days, that is, no LH value is measured for 6/11/2016 and no LH value is measured for 7/11/2016, and the measurement of the LH value is continued from 8/11/2016, and if 5 days are continuously measured, the measured LH values are still all smaller than the first LH preset value, the measurement of the LH values is continued for the next two days, that is, no LH value is measured for 13/11/2016 and 14/2016, and the LH value is continued to be measured from 15/11/2016, and so on until an LH peak value is detected, and when the LH peak value is larger than the second LH preset value, the date on which the LH peak value is detected is taken as the detection cutoff day.
In the embodiment of the present invention, in order to accurately obtain the ovulation day, the measurement frequency in each day may be increased, and therefore, optionally, if the LH value measured in the ovulation detection day is greater than or equal to the first LH preset value and is less than or equal to the second LH preset value, the detection unit 320 is suggested to measure the LH value once every first preset interval time until the LH peak value is detected, and the LH peak value is greater than the second LH preset value; if the measured LH value in the ovulation detection day is greater than the second LH preset value and the LH peak value does not appear yet, the detecting unit 320 is suggested to measure the LH value once every second preset interval time until the LH peak value is detected, and the LH peak value is greater than the second LH preset value, wherein the second preset interval time is less than the first preset interval time.
In the embodiment of the present invention, optionally, the first LH preset value is 20 to 30mIU/ml, the second LH preset value is 40 to 50mIU/ml, the third preset number of days is 8 to 12 days, the first preset interval time is 2 to 6 hours, and the second preset interval time is 1 to 3 hours.
In embodiments of the invention, optionally, the ovulation test day and/or the recommended test frequency/amount for the ovulation test day is provided to the user. Optionally, a graphical interaction is provided to the user. As can be seen with reference to figures 1D and 1E,
fig. 1D is a schematic diagram of an example of an interactive interface of the device 30 for inputting physiological information of a user and outputting ovulation test time, in which the user inputs physiological information by selecting yes or no at corresponding times from the options "start of menstrual period" and "end of menstrual period", so as to obtain specific time of menstrual period, such as 6/2016 to 10/6/2016, and further record the time of the same room, and then the device 30 displays a "suggested LH test" time according to the information input by the user: year 2016, 6/19 to year 2016, 6/23.
Further, the device 30 may recommend a specific detection time at the date of the suggested LH detection according to the physiological detection value, as shown in fig. 1E, and the recommended specific detection time period is 10:00-14:00, 14:00-18:00, 18:00-20: 00.
Referring to fig. 4, in an embodiment of the present invention, there is provided an apparatus 40 for determining ovulation detection time based on an electronic device, including:
an obtaining unit 400, configured to obtain physiological information and a physiological detection value of a user;
the determining unit 410 is configured to determine an ovulation detection time according to the physiological information and the physiological detection value.
In the embodiment of the present invention, the physiological information may include at least one of information on whether a physiological cycle is regular, information on a duration of the physiological cycle, information on a start date of the physiological cycle, and information on an end date of the physiological cycle. Of course, other information may also be included and will not be described in detail herein. For example, the device 40 presents the user with the options of regular and irregular physiological cycles, and can acquire the information whether the physiological cycle of the user is regular or not based on the selection of the user; the device 40 presents an input interface or an option selection interface of the physiological cycle duration to the user, and acquires the information of the physiological cycle duration of the user based on the selection of the days or the filling of the days by the user; the device 40 may obtain information on the user's date of initiation of the physiological cycle based on the user's selection of whether menstruation entered on a certain day begins; the device 40 may obtain information on the expiration date of the user's physiological cycle based on the user's selection of whether menstruation entered on a certain day is ended. Or the device 40 acquires the information whether the physiological cycle is regular and/or the information of the physiological cycle duration based on the physiological cycle start date and the physiological cycle end date input by the user.
In embodiments of the invention, optionally, the ovulation test day and/or the recommended test frequency/amount for the ovulation test day is provided to the user. Optionally, a graphical interaction is provided to the user. As can be seen with reference to figures 1D and 1E,
fig. 1D is a schematic diagram of an example of an interactive interface of the device 40 for inputting physiological information of a user and outputting ovulation test time, in which the user inputs physiological information by selecting yes or no at corresponding times from the options "start of menstrual period" and "end of menstrual period", so as to obtain specific time of menstrual period, such as 6/2016 to 10/6/2016, and further record the time of the same room, and then the device 40 displays a "suggested LH test" time according to the information input by the user: year 2016, 6/19 to year 2016, 6/23.
Further, the apparatus 40 may recommend specific detection time periods on the date of suggesting LH detection, as shown in fig. 1E, the recommended specific detection time periods are 10:00-14:00, 14:00-18:00, 18:00-20: 00.
In this embodiment of the present invention, the determining unit 410 includes a determining unit 410A, a detecting unit 410B, a start date determining unit 410C, and a deadline determining unit 410D, where:
the judging unit 410A is configured to judge whether the physiological cycle of the user is regular according to the physiological information;
the start date determining unit 410C is configured to determine a first start date of the physiological cycle with the shortest distance from the current date, and determine the detection start date according to the first start date and a judgment result of whether the physiological cycle is regular;
the detecting unit 410B is configured to measure a physiological detection value from the detection start day;
the deadline determining unit 410D is configured to determine a detection deadline according to the physiological detection value, and use a time period between the detection start date and the detection deadline as an ovulation detection date.
In this embodiment of the present invention, optionally, the starting date determining unit 410C determines the starting date of detection according to the first starting date and the judgment result of whether the physiological cycle is regular, specifically:
when the judging unit 410A judges the physiological cycle rule, acquiring a target number of days, and determining the detection start date according to the target number of days and the first start date;
when the determining unit 410A determines that the physiological cycle is irregular, a date which is located after the first start day and is a first preset number of days away from the first start day is used as the detection start day.
That is, if the physiological cycle is regular, the detection start day is determined by determining the detection start day according to the target number of days and the first start day, and if the physiological cycle is irregular, the detection start day is directly determined as the date which is located after the first start day and is a first preset number of days away from the first start day.
In this embodiment of the present invention, further, the determining unit 410A is further configured to determine whether the physiological cycle is known;
when the starting day determining unit 410C obtains the target number of days, the method specifically includes:
if the judging unit 410A judges that the physiological cycle is known, taking the number of days of the physiological cycle as the target number of days;
if the determining unit 410A determines that the physiological cycle is unknown, the physiological cycle is calculated, and the minimum value between the number of days of the calculated physiological cycle and 28 is used as the target number of days.
In the embodiment of the invention, if the user inputs the physiological cycle of the user, the physiological cycle can be judged to be known, if the user does not input the physiological cycle of the user, but the initial day and the final day of each physiological cycle are input, the physiological cycle is unknown, the physiological cycle needs to be calculated, the number of days of the calculated physiological cycle is compared with 28, and the minimum value obtained by comparison is taken as the target number of days.
For example, if the user inputs that the physiological cycle is 30 days, the physiological cycle is determined to be known, and the target number of days is directly 30; if the user does not input the specific duration of the physiological cycle, but inputs the start date and the end date of the physiological cycle, it is determined that the physiological cycle is unknown, the current time is 2016, 12, and 13 days, the start date of the physiological cycle of 2016, 11, and 2 days, and the end date is 2016, 11, and 8 days, the start date of the physiological cycle of 2016, 10, and 3 days, and the end date is 2016, 10, and 10 days, it is necessary to calculate the time period between 2016, 10, and 3 days, and 2016, and 11, and 2 days, and compare the time period between 2016, 3 days, and 2 days, 10, and 2016, 11, and 2 days, with 30 days and 28 days, and take the minimum value of 28 days as the target number of days.
In an embodiment of the present invention, optionally, when the starting day determining unit 410C calculates the physiological cycle, specifically:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
For example, when the current time is 2016, 12 and 13 days, the physiological cycle for 2016, 11 and 11 months is 2016, 2 days to 8 days, and the physiological cycle for 2016, 10 months is 2016, 3 days to 10 days, 10 months and 10 days, respectively, the physiological cycle is 30 days between 2016, 3 days to 2 days, 11 months and 10 months.
In this embodiment of the present invention, optionally, the starting day determining unit 410C determines the detection starting time according to the target number of days and the first starting day, specifically:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
Wherein optionally the relation between the target number of days and the corresponding reference number of days is as shown in table 1.
For example, when the target number of days is 21 days, the reference number of days is 6 days, i.e., a date of 6 days from the first start date onward is taken as the detection start date; when the target day is 34 days, the reference day is 17 days, and a day counting 17 days from the first start day onward is taken as the detection start day. As can be seen from table 1, when the target days are increasing, the reference days are also increasing gradually in the overall trend, the same reference day may correspond to more than 1 target day, such as 6 days when the target days are 21 days and 22 days, but the reference days are increasing gradually with the target days in the overall trend, i.e. the reference days are positively correlated with the target days.
Table 1 is merely an example of the correspondence relationship between the target days and the reference days, and is not limited thereto in practical applications, and will not be described in detail here. The correspondence between the target number of days and the reference number of days may be stored in the electronic device, and the correspondence is invoked for determining the detection start day during calculation.
In an embodiment of the present invention, optionally, the first preset number of days is 6 days.
In an embodiment of the present invention, optionally, the expiration date determining unit 410D determines the detection expiration date according to the physiological detection value, specifically:
determining the detection deadline based on the LH value.
In this embodiment of the present invention, further, the apparatus further includes a detecting unit 410B, configured to measure an LH value from the detection start date;
the cutoff day determining unit 410D determines the detection cutoff time according to the LH value, specifically:
if the physiological cycle is regular, when all LH values measured by the detecting unit 410B from the detection start date are less than or equal to a first LH preset value, taking a date which is a third preset number of days apart from the detection start date as the detection deadline;
if the physiological cycle is regular, when the number of days for measuring the LH value does not reach the third preset number of days from the detection start day, the LH peak value occurs in all measured LH values, and the LH peak value is greater than a second LH preset value, the date on which the LH peak value is detected is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
That is, if the circadian cycle is regular, the determination of the detection deadline has two ways, if all the measured LH values from the detection start date are less than the first LH preset value, in which case the detection is stopped if the number of measured days has reached the third preset number of days, if the measured LH values from the detection start date have a LH peak when the third preset number of days has not been reached, and the LH peak is greater than the second LH preset value, in which case the date on which the LH peak is detected is taken as the detection deadline.
For example, 1/11/2016 is a detection start day, 7/the third preset days are days, the measurement of the LH value is started from 1/11/2016, and if 7/7 consecutive days are measured, the measurement of the LH value is stopped from 8 th day when the measured LH values are all smaller than the first LH preset value; if the LH peak value occurs after continuously measuring for 5 days and is greater than the second LH preset value, in this case, although the measured days do not reach the third preset days of 7 days, the measurement of the LH value is still stopped, and 2016, 11, and 5 days is taken as a detection deadline.
In the foregoing, it is described how to determine the detection deadline according to the LH value when the physiological cycle is regular, and in practical applications, there is also a case that the physiological cycle is irregular, and the apparatus further includes a detection unit 410B configured to measure the LH value from the detection start date;
the cutoff date determining unit 410D determines the detection cutoff date according to the LH value, specifically:
if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection start date are less than or equal to a first LH preset value, the detecting unit 410B continues to perform the step of measuring LH values from a date spaced by two days from the second preset number of days from the detection start date until an LH peak value is detected, and when the LH peak value is greater than the second LH preset value, the date at which the LH peak value is detected is taken as the detection cutoff date, wherein the second LH preset value is greater than the first LH preset value.
For example, if 1/2016 is a detection start day, 5 days are preset second days, the LH value is measured from 1/2016, and if 5 days are continuously measured, the measured LH values are all smaller than the first LH preset value, the LH values are stopped to be measured for the next two days, that is, no LH value is measured for 6/2016 and 7/2016 and the LH value is continuously measured from 8/2016, and if 5 days are continuously measured, the measured LH values are still smaller than the first LH preset value, the LH values are stopped to be measured for the next two days, that is, no LH value is measured for 13/2016 and 14/2016, the LH value is continuously measured from 15/2016, and so on, until the LH peak value is detected, and the LH peak value is larger than the second preset LH value, the date on which the LH peak value is detected is taken as the detection cutoff day.
In the embodiment of the present invention, in order to accurately obtain the ovulation day, the measurement frequency in each day may be increased, and therefore, optionally, if the LH value measured by the detection unit 410B in the ovulation detection day is greater than or equal to the first LH preset value and is less than or equal to the second LH preset value, it is recommended that the detection unit 410B measures the LH value once every first preset interval time until the LH peak value is detected, and the LH peak value is greater than the second LH preset value; if the LH value measured by the detection unit 410B within the ovulation detection day is greater than the second LH preset value and the LH peak value does not occur yet, it is recommended that the detection unit 410B measure the LH value once every second preset interval time until the LH peak value is detected, and the LH peak value is greater than the second LH preset value, where the second preset interval time is less than the first preset interval time.
In the embodiment of the present invention, optionally, the first LH preset value is 20 to 30mIU/ml, the second LH preset value is 40 to 50mIU/ml, the third preset number of days is 8 to 12 days, the first preset interval time is 2 to 6 hours, and the second preset interval time is 1 to 3 hours.
In a specific embodiment, determining the detection deadline based on the physiological detection value may include the following:
in a recommended period of a third preset number of days (for example, 5 days) after the detection start day, if an LH peak is detected and the peak value is greater than 45mIU/ml, which indicates that ovulation may occur, the date when the peak value is detected is taken as a detection deadline, the recommendation in the current physiological period is stopped, and the detection date prompt of LH is updated to the next period.
After the lapse of a recommended period of a third preset number of days (e.g., 5 days) after the start date of the test, if all measured LH values are < 25 mIU/ml:
for a user with a regular physiological cycle: continuous detection for a third preset number of days, for example, 5 days, is continuously recommended. If the peak value of LH is detected within 5 days and the peak value is more than 45mIU/ml, which indicates that ovulation possibly occurs, the date of detecting the peak value is taken as a detection deadline, the recommendation in the current physiological cycle is stopped, and meanwhile, the detection date of LH is reminded to update to the next cycle; if the peak value does not appear within 5 days, taking the 5 th day as a detection deadline, and stopping the detection recommendation of the current physiological cycle;
for users with irregular physiological cycles: after 2 days, continuous detection is continuously recommended for a third preset number of days, for example, 5 days. And by analogy, the recommendation in the current physiological cycle is stopped until the LH peak is detected, and the recommendation in the next physiological cycle is entered.
In the detection, if the detected value of a user on a certain day is more than or equal to 25mIU/mL and less than or equal to 45mIU/mL, the detection is prompted to be performed once every 2-4 hours, and the detection time is updated synchronously; if the user detects that the value is more than 45mIU/mL at a certain time but the peak value does not appear yet, the detection is prompted to be performed every 2 hours in the future.
In this scheme, the ovulation test day is determined based on the physiological information and the physiological test value, avoiding the need to rely solely on the starting time of the next menstruation, thus improving the accuracy of determining the ovulation test day.
Exemplary device
Having described the method and apparatus of an exemplary embodiment of the invention, next, an apparatus for determining ovulation detection time based on an electronic device according to another exemplary embodiment of the invention is described.
As will be appreciated by one skilled in the art, aspects of the present invention may be embodied as a system, method or program product. Thus, various aspects of the invention may be embodied in the form of: an entirely hardware embodiment, an entirely software embodiment (including firmware, microcode, etc.) or an embodiment combining hardware and software aspects that may all generally be referred to herein as a "circuit," module "or" system.
In some possible embodiments, the device for electronic device based determination of ovulation detection time according to the present invention may comprise at least one processing unit, and at least one memory unit. Wherein the memory unit stores program code which, when executed by the processing unit, causes the processing unit to perform the steps of the method for electronic device based ovulation detection time determination according to various exemplary embodiments of the present invention described in the "exemplary methods" section above in this specification. For example, the processing unit may perform step 100 as shown in fig. 1: judging whether the physiological cycle of the user is regular or not; step 110: determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not; step 120: determining a detection deadline, and setting a time period between the detection start date and the detection deadline as an ovulation detection date.
For another example, the processing unit may perform step 200 as shown in fig. 2: acquiring physiological information and a physiological detection value of a user; step 210: and determining ovulation detection time according to the physiological information and the physiological detection value.
An apparatus 50 for electronic device based determination of ovulation test timing according to this embodiment of the invention is described below with reference to figure 5. The device 50 for electronically determining ovulation test timing shown in figure 5 is only an example and should not be taken as limiting the function and scope of use of embodiments of the present invention in any way.
As shown in fig. 5, the apparatus 50 for electronic based determination of ovulation test time is in the form of a general purpose computing device. Components of the apparatus 50 for electronically determining ovulation detection time may include, but are not limited to: the at least one processing unit 16, the at least one memory unit 28, and the bus 18 that connects the various system components (including the memory unit 28 and the processing unit 16).
Bus 18 represents one or more of any of several types of bus structures, including a memory bus or memory controller, a peripheral bus, an accelerated graphics port, a processor, or a local bus using any of a variety of bus architectures.
The storage unit 28 may include readable media in the form of volatile memory, such as Random Access Memory (RAM)31 and/or cache memory 32, and may further include Read Only Memory (ROM) 34.
Storage unit 28 may also include a program/utility 41 having a set (at least one) of program modules 42, such program modules 42 including, but not limited to: an operating system, one or more application programs, other program modules, and program data, each of which, or some combination thereof, may comprise an implementation of a network environment.
The device 50 for electronic device based determination of ovulation test time may also be in communication with one or more external devices 14 (e.g. keyboard, pointing device, bluetooth device, etc.), with one or more devices enabling the user to interact with the device 50 for electronic device based determination of ovulation test time, and/or with any device (e.g. router, modem, etc.) enabling the device 50 for electronic device based determination of ovulation test time to communicate with one or more other computing devices. Such communication may be through an input/output (I/O) interface 22. Also, the device 50 for electronically determining ovulation test timing may also communicate with one or more networks (e.g. a Local Area Network (LAN), a Wide Area Network (WAN) and/or a public network, such as the internet) via the network adaptor 21. As shown, the network adaptor 21 communicates via the bus 18 with the other modules of the device 50 for determining ovulation test times based on the electronic device. It should be understood that although not shown in the figures, other hardware and/or software modules may be used in conjunction with the device 50 for electronic-based determination of ovulation detection times, including but not limited to: microcode, device drivers, redundant processing units, external disk drive arrays, RAID systems, tape drives, and data backup storage systems, among others.
Exemplary program product
In some possible embodiments, aspects of the invention may also be implemented in the form of a program product comprising program code for causing an apparatus to perform the steps of the method for determining ovulation detection time based on an electronic device according to various exemplary embodiments of the invention described in the "exemplary methods" section above of this specification, when said program product is run on the device, e.g. the device may perform the steps 100 as shown in fig. 1: judging whether the physiological cycle of the user is regular or not; step 110: determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not; step 120: determining a detection deadline, and setting a time period between the detection start date and the detection deadline as an ovulation detection date.
For example, the device may perform step 200 as shown in fig. 2: acquiring physiological information and a physiological detection value of a user; step 210: determining ovulation detection time according to the physiological information and the physiological detection value
The program product may employ any combination of one or more readable media. The readable medium may be a readable signal medium or a readable storage medium. A readable storage medium may be, for example, but not limited to, an electronic, magnetic, optical, electromagnetic, infrared, or semiconductor system, apparatus, or device, or any combination of the foregoing. More specific examples (a non-exhaustive list) of the readable storage medium include: an electrical connection having one or more wires, a portable disk, a hard disk, a Random Access Memory (RAM), a read-only memory (ROM), an erasable programmable read-only memory (EPROM or flash memory), an optical fiber, a portable compact disc read-only memory (CD-ROM), an optical storage device, a magnetic storage device, or any suitable combination of the foregoing.
As shown in fig. 6, a program product 60 for electronic device-based ovulation detection time determination according to an embodiment of the present invention is depicted, which may employ a portable compact disc read only memory (CD-ROM) and include program code, and may be run on a terminal device, such as a personal computer. However, the program product of the present invention is not limited in this regard and, in the present document, a readable storage medium may be any tangible medium that can contain, or store a program for use by or in connection with an instruction execution system, apparatus, or device.
A readable signal medium may include a propagated data signal with readable program code embodied therein, for example, in baseband or as part of a carrier wave. Such a propagated data signal may take any of a variety of forms, including, but not limited to, electro-magnetic, optical, or any suitable combination thereof. A readable signal medium may also be any readable medium that is not a readable storage medium and that can communicate, propagate, or transport a program for use by or in connection with an instruction execution system, apparatus, or device.
Program code embodied on a readable medium may be transmitted using any appropriate medium, including but not limited to wireless, wireline, optical fiber cable, RF, etc., or any suitable combination of the foregoing.
Program code for carrying out operations for aspects of the present invention may be written in any combination of one or more programming languages, including an object oriented programming language such as Java, C + + or the like and conventional procedural programming languages, such as the "C" programming language or similar programming languages. The program code may execute entirely on the user's computing device, partly on the user's device, as a stand-alone software package, partly on the user's computing device and partly on a remote computing device, or entirely on the remote computing device or server. In the case of a remote computing device, the remote computing device may be connected to the user computing device over any kind of network, including a Local Area Network (LAN) or a Wide Area Network (WAN), or may be connected to an external computing device (e.g., over the internet using an internet service provider).
It should be noted that although in the above detailed description several means or sub-means of the apparatus for electronically based determination of ovulation detection time are mentioned, this division is not mandatory only. Indeed, the features and functions of two or more of the devices described above may be embodied in one device, according to embodiments of the invention. Conversely, the features and functions of one apparatus described above may be further divided into embodiments by a plurality of apparatuses.
Moreover, while the operations of the method of the invention are depicted in the drawings in a particular order, this does not require or imply that the operations must be performed in this particular order, or that all of the illustrated operations must be performed, to achieve desirable results. Additionally or alternatively, certain steps may be omitted, multiple steps combined into one step execution, and/or one step broken down into multiple step executions.
While the spirit and principles of the invention have been described with reference to several particular embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, nor is the division of aspects, which is for convenience only as the features in such aspects may not be combined to benefit. The invention is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

Claims (37)

1. An electronic device based method of determining ovulation detection time, comprising:
judging whether the physiological cycle of the user is regular or not;
determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not;
determining a detection deadline, and taking a time period between the detection start date and the detection deadline as an ovulation detection date;
determining a detection deadline, comprising: measuring the LH value of luteinizing hormone from the start day of the assay, determining the cutoff day of the assay from the LH value;
determining the detection deadline from the LH value, comprising: if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day are less than or equal to a first LH preset value, continuing to perform the step of measuring the LH values from a date which is two days away from the detection starting day by the second preset number of days until an LH peak value is detected, and taking the date on which the LH peak value is detected as the detection deadline when the LH peak value is greater than the second LH preset value, wherein the second LH preset value is greater than the first LH preset value.
2. The method of claim 1, wherein determining the detection start date according to the determination result of whether the first start date and the physiological cycle are regular comprises:
when the physiological cycle rule is judged, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the physiological cycle is judged to be irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
3. The method of claim 2, obtaining a target number of days, comprising:
determining whether the physiological cycle is known;
if so, taking the days of the physiological cycle as the target days;
otherwise, calculating the physiological cycle, and taking the minimum value of the calculated days of the physiological cycle and 28 as the target days.
4. The method of claim 3, calculating the physiological cycle, comprising:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
5. The method of claim 2, determining the detection start day based on the target number of days and the first start day, comprising:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
6. The method of any one of claims 2-5, wherein the first predetermined number of days is 6 days.
7. The method as claimed in claim 1, determining the detection deadline based on the LH value comprises:
if the physiological cycle is regular, when all LH values measured from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline; and when the days for measuring the LH values do not reach the third preset days from the detection starting day, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is taken as the detection stopping day, wherein the second LH preset value is larger than the first LH preset value.
8. The method as claimed in claim 7, wherein if the measured LH value is greater than or equal to the first LH preset value and less than or equal to the second LH preset value within the ovulation detection day, it is recommended to measure the LH value every first preset interval until an LH peak value is detected, and the LH peak value is greater than the second LH preset value; and if the LH value measured on the ovulation detection day is larger than the second LH preset value and the LH peak value does not appear, the LH value is recommended to be measured once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
9. The method as claimed in claim 8, wherein the first predetermined LH value is 20-30mIU/ml, the second predetermined LH value is 40-50mIU/ml, the third predetermined number of days is 8-12 days, the first predetermined interval time is 2-6 hours, and the second predetermined interval time is 1-3 hours.
10. An electronic device based method of determining ovulation detection time, comprising:
acquiring physiological information and a physiological detection value of a user;
determining ovulation detection time according to the physiological information and the physiological detection value;
determining a detection deadline based on the physiological detection value, comprising: determining the detection cutoff day from luteinizing hormone LH values;
determining the detection deadline from the LH value, comprising: if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the beginning detection day are less than or equal to a first LH preset value, the step of measuring the LH values is continuously executed from the date which is two days away from the beginning detection day by the second preset number of days until an LH peak value is detected, and the LH peak value is greater than a second LH preset value, the date at which the LH peak value is detected is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
11. The method of claim 10, wherein determining an ovulation test time based on said physiological information and said physiological test value comprises:
judging whether the physiological cycle of the user is regular or not according to the physiological information;
determining a first starting day of the physiological cycle with the shortest distance from the current date, and determining the detection starting day according to the first starting day and the judgment result of whether the physiological cycle is regular or not;
measuring a physiological test value from the test start day, determining a test cutoff day based on the physiological test value, and taking a time period between the test start day and the test cutoff day as an ovulation test day.
12. The method of claim 11, wherein determining the detection start date according to the determination result of whether the first start date and the physiological cycle are regular comprises:
when the physiological cycle rule is judged, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the physiological cycle is judged to be irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
13. The method of claim 12, obtaining a target number of days, comprising:
determining whether the physiological cycle is known;
if so, taking the days of the physiological cycle as the target days;
otherwise, calculating the physiological cycle, and taking the minimum value of the calculated days of the physiological cycle and 28 as the target days.
14. The method of claim 13, calculating the physiological cycle, comprising:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
15. The method of claim 12, determining the detection start day based on the target number of days and the first start day, comprising:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
16. The method of claim 12, wherein the first predetermined number of days is 6 days.
17. The method as claimed in claim 10, determining the detection deadline based on the LH value comprises:
if the physiological cycle is regular, when all LH values measured from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline;
and if the physiological cycle rule is adopted, when the number of days for measuring the LH values does not reach the third preset number of days from the detection starting day, the LH peak value appears in all the measured LH values, and the LH peak value is greater than a second LH preset value, the date for detecting the LH peak value is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
18. The method as claimed in claim 17, wherein if the LH value measured within the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, it is recommended to measure the LH value every first preset interval until an LH peak value is detected, and the LH peak value is greater than the second LH preset value; and if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
19. The method as claimed in claim 18, wherein the first LH preset value is 20-30 mIU/ml; the second LH preset value is 40-50 mIU/ml; the third preset number of days is 8-12 days; the first preset interval time is 2-6 hours; the second preset interval time is 1-3 hours.
20. An electronic device based apparatus for determining ovulation detection time, comprising:
the judging unit is used for judging whether the physiological cycle of the user is regular or not;
the determining unit is used for determining a first starting day of the physiological cycle with the shortest distance from the current date and determining a detection starting day according to the first starting day and a judgment result of whether the physiological cycle is regular or not;
the determining unit is further used for determining a detection deadline, and taking a time period between the detection start date and the detection deadline as an ovulation detection date;
the determining unit determines the detection cut-off time of day, specifically: measuring the LH value of luteinizing hormone from the start day of the assay, determining the cutoff day of the assay from the LH value;
the apparatus further includes a detection unit for measuring an LH value from the detection start day;
the determining unit determines the detection cutoff time of day according to the LH value, specifically: if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day by the detection unit are less than or equal to a first LH preset value, the step of measuring the LH values is continuously executed from a date which is two days away from the second preset number of days from the detection starting day until an LH peak value is detected, and when the LH peak value is greater than the second LH preset value, the date at which the LH peak value is detected is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
21. The apparatus according to claim 20, wherein the determining unit determines the detection start date according to the first start date and the judgment result of whether the physiological cycle is regular, specifically:
when the judging unit judges the physiological cycle rule, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the judging unit judges that the physiological cycle is irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
22. The apparatus according to claim 21, wherein the determining unit is further configured to determine whether the physiological cycle is known;
when the determining unit obtains the target days, the determining unit specifically includes:
if the judging unit judges that the physiological cycle is known, taking the days of the physiological cycle as the target days;
if the judging unit judges that the physiological cycle is unknown, the physiological cycle is calculated, and the minimum value of the number of days of the calculated physiological cycle and 28 is used as the target number of days.
23. The apparatus according to claim 22, wherein the determining unit calculates the physiological cycle by:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
24. The apparatus according to claim 21, wherein the determining unit determines the detection start time based on the target number of days and the first start day, and specifically:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
25. The device of any one of claims 21-24, wherein the first predetermined number of days is 6 days.
26. The apparatus as claimed in claim 20, further comprising a detection unit for measuring an LH value from the detection start day;
the determining unit determines the detection cutoff time of day according to the LH value, specifically:
if the physiological cycle is regular, when all LH values measured by the detection unit from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline; and when the days for measuring the LH values do not reach the third preset days from the detection starting day, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is taken as the detection stopping day, wherein the second LH preset value is larger than the first LH preset value.
27. The apparatus as claimed in claim 26, wherein if the LH value measured during the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, the detecting unit is advised to measure the LH value every first preset interval until an LH peak value is detected, and the LH peak value is greater than the second LH preset value; if the measured LH value in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the LH value is recommended to be measured by the detection unit at intervals of a second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
28. The apparatus of claim 27, wherein the first LH preset value is 20-30 mIU/ml; the second LH preset value is 40-50 mIU/ml; the third preset number of days is 8-12 days; the first preset interval time is 2-6 hours; the second preset interval time is 1-3 hours.
29. An electronic device based apparatus for determining ovulation detection time, comprising:
the acquisition unit is used for acquiring physiological information and a physiological detection value of a user;
the determining unit is used for determining ovulation detection time according to the physiological information and the physiological detection value;
the determining unit comprises a judging unit, a detecting unit, a starting date determining unit and a deadline determining unit;
the judging unit is used for judging whether the physiological cycle of the user is regular or not according to the physiological information;
the starting date determining unit is used for determining a first starting date of the physiological cycle with the shortest distance from the current date and determining a detection starting date according to the first starting date and the judgment result of whether the physiological cycle is regular or not;
the detection unit is used for measuring a physiological detection value from the detection starting day and comprises: measuring LH values from the detection start day;
the deadline determining unit is configured to determine a detection deadline according to the physiological detection value, and determine a time period between the detection start date and the detection deadline as an ovulation detection date by the deadline determining unit, where the determining the detection deadline according to the physiological detection value specifically includes: determining the detection cutoff day from luteinizing hormone LH values;
wherein, the cutoff date determining unit determines the detection cutoff date according to the LH value, specifically: if the physiological cycle is irregular, when all LH values measured within a second preset number of days from the detection starting day by the detection unit are less than or equal to a first LH preset value, the step of measuring the LH values is continuously executed from a date which is two days away from the second preset number of days from the detection starting day until an LH peak value is detected, and when the LH peak value is greater than the second LH preset value, the date at which the LH peak value is detected is taken as the detection deadline, wherein the second LH preset value is greater than the first LH preset value.
30. The apparatus according to claim 29, wherein the start date determining unit determines the detection start date according to the first start date and the judgment result of whether the physiological cycle is regular, and specifically:
when the judging unit judges the physiological cycle rule, acquiring a target number of days, and determining the detection starting date according to the target number of days and the first starting date;
and when the judging unit judges that the physiological cycle is irregular, taking a date which is positioned after the first starting date and is a first preset number of days away from the first starting date as the detection starting date.
31. The apparatus according to claim 30, wherein the determining unit is further configured to determine whether the physiological cycle is known;
when the starting day determining unit obtains the target number of days, the method specifically comprises the following steps:
if the judging unit judges that the physiological cycle is known, taking the days of the physiological cycle as the target days;
if the judging unit judges that the physiological cycle is unknown, the physiological cycle is calculated, and the minimum value of the number of days of the calculated physiological cycle and 28 is used as the target number of days.
32. The apparatus according to claim 31, wherein the start date determining unit calculates the physiological cycle by:
determining a first starting day of a physiological cycle with the shortest distance from the current date and a second starting day of the physiological cycle adjacent to the physiological cycle corresponding to the first starting day, and taking the time period between the first starting day and the second starting day as the physiological cycle.
33. The apparatus according to claim 30, wherein the start date determining unit determines the detection start date based on the target number of days and the first start date, and specifically:
determining a reference number of days corresponding to the target number of days, wherein the reference number of days is positively correlated with the target number of days;
taking a date which is located after the first start day and after the reference number of days from the first start day as the detection start day.
34. The apparatus of claim 30, wherein the first predetermined number of days is 6 days.
35. The apparatus as claimed in claim 29, wherein the cutoff-day determining unit determines the detection cutoff-day time based on an LH value, specifically:
if the physiological cycle is regular, when all LH values measured by the detection unit from the detection starting date are less than or equal to a first LH preset value, taking the date which is a third preset number of days away from the detection starting date as the detection deadline;
if the physiological cycle rule is adopted, when the detecting unit starts from the detection starting day, the number of days for measuring the LH values does not reach the third preset number of days, LH peak values appear in all measured LH values, and the LH peak values are larger than a second LH preset value, the date for detecting the LH peak values is used as the detection deadline, wherein the second LH preset value is larger than the first LH preset value.
36. The apparatus as claimed in claim 35, wherein if the LH value measured by the detecting unit during the ovulation detection day is greater than or equal to the first LH preset value and less than or equal to the second LH preset value, the detecting unit is advised to measure the LH value every first preset interval until an LH peak value is detected, and the LH peak value is greater than the second LH preset value; if the LH value measured by the detection unit in the ovulation detection day is larger than the second LH preset value and no LH peak value appears, the detection unit is recommended to measure the LH value once every second preset interval time until the LH peak value is detected, and the LH peak value is larger than the second LH preset value, wherein the second preset interval time is smaller than the first preset interval time.
37. The apparatus of claim 36, wherein the first LH preset value is 20-30 mIU/ml; the second LH preset value is 40-50 mIU/ml; the third preset number of days is 8-12 days; the first preset interval time is 2-6 hours; the second preset interval time is 1-3 hours.
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