[go: up one dir, main page]
More Web Proxy on the site http://driver.im/

WO2014190522A1 - 量度皮肤阻抗之系统与方法 - Google Patents

量度皮肤阻抗之系统与方法 Download PDF

Info

Publication number
WO2014190522A1
WO2014190522A1 PCT/CN2013/076488 CN2013076488W WO2014190522A1 WO 2014190522 A1 WO2014190522 A1 WO 2014190522A1 CN 2013076488 W CN2013076488 W CN 2013076488W WO 2014190522 A1 WO2014190522 A1 WO 2014190522A1
Authority
WO
WIPO (PCT)
Prior art keywords
signal
frequency
programmable
medium
skin
Prior art date
Application number
PCT/CN2013/076488
Other languages
English (en)
French (fr)
Inventor
李后杰
李训福
Original Assignee
Lee Hou-Chieh
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Lee Hou-Chieh filed Critical Lee Hou-Chieh
Priority to PCT/CN2013/076488 priority Critical patent/WO2014190522A1/zh
Publication of WO2014190522A1 publication Critical patent/WO2014190522A1/zh

Links

Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/05Detecting, measuring or recording for diagnosis by means of electric currents or magnetic fields; Measuring using microwaves or radio waves 
    • A61B5/053Measuring electrical impedance or conductance of a portion of the body
    • A61B5/0531Measuring skin impedance

Definitions

  • the invention relates to a system and method for injecting high-medium and low-frequency signals into human skin to measure the impedance of the skin to the signal, in particular to one of the high-medium-low-frequency injection signals, the frequency, waveform and power of the main wave.
  • the pause time, and the frequency and waveform of the carrier and the waveform can be programmed to be output in a safely specified value, which is injected into the human skin in series, and is measured and processed by the measurement signal to measure the human skin (eg The meridian, acupoint, etc.
  • the impedance change value (referred to as the electrical spectrum value) of the injected signal is used (1M ⁇ is the system and method for detecting the health condition of the body, and (2) is the high-medium-low frequency injection signal. A good reference for the set value.
  • the high-medium and low-frequency treatment instrument can treat the pain of the body.
  • the Chinese and Western medicine industry has been working for a long time. The effect of the instrument is determined by the waveform, frequency, pause time and power as the main output physical quantity.
  • the traditional high-middle and low-frequency treatment instrument has the following disadvantages: a) The power of the traditional general high, medium and low frequency therapy device can only be adjusted simply and cannot be set programmatically; (b) For the frequency of the traditional therapeutic device, generally only the user can only have a few frequencies.
  • Selection can not be set programmatically; (c) For the waveform of the traditional output, generally only a few fixed waveforms can be selected, which cannot be programmed by the user; (dM output power is generally For continuous waveform output or for several selective pause times, the pause time between waves and waves cannot be programmed; and (e) the waveform of the conventional output without carrier frequency and waveform can be programmed .
  • the traditional high school and low frequency therapy device does not combine the measurement of the impedance of the skin to the high, medium and low frequency injection signals. Therefore, the traditional ones have the following disadvantages: (1) The traditional high, medium and low frequency therapy device has no measurement design of the impedance change value of the injected signal. Therefore, the traditional high school and low frequency therapy device can not provide the user with the frequency, waveform, power, and pause time as the optimal setting value of the output of the instrument (refers to the electrical spectrum value tends to fall within the conventional value range after high, medium and low frequency treatment).
  • the reference of the internal is to obtain the better curative effect of the high, medium and low frequency therapeutic apparatus; (2) the conventional apparatus for measuring the change of the impedance of the implanted electric wave, which only stays in the measure of the impedance change of the direct current injected into the human body, A device for measuring the change in impedance of the skin by direct current is not able to measure the impedance change of the frequency and waveform signal applied to the non-direct current of the human body.
  • the measurement of the change in DC electrical impedance of human skin is currently recognized as a method for detecting the health of the body. It has been carried out for many years, such as the Japanese Good Guide System and the West German Dr. VoLL System. But for people The measurement system of the impedance change value of the high-medium-low-frequency (non-direct current) signal injected into the skin is not yet available as a detection system and method for the health of the body.
  • Human skin measures the change of DC electrical impedance to detect physical health, such as the Japanese good guide system, which can only provide non-real-time physical health of the subject in a recent period of time (how long is uncertain)
  • the status message does not provide real-time information on the subject's infectious diseases, related organ degradation and related tumors.
  • the present invention provides a measurement system and method for measuring the impedance change value (electrical spectrum value) of human body skin (such as the meridian, acupoint, etc. of the human body) for injecting various frequencies and waveform signals.
  • the impedance change value electrical spectrum value
  • the subject's relevant infectious diseases, related organ degradation and related tumor information can be provided in real time.
  • the present invention relates to a system and method for injecting a signal of high, medium, and low frequency into human skin to measure the impedance of the skin to the signal.
  • the system of the present invention includes:
  • An energy output device having a high, medium, and low frequency for generating a high, medium, and low frequency injection signal for applying the injection signal to a part of a subject or a user's body as a physical examination of the subject a device for injecting a signal or a therapeutic wave for treating the disease or pain by the user; and a measuring device for the impedance of the skin to the injected signal, connecting to another part of the subject's body, and the subject being tested
  • the injection signal of the body forms a circuit loop, and outputs a measurement signal through the circuit loop for measuring the impedance change value (electrical spectrum value) of the skin of the test subject according to whether the electrical spectrum value falls. It is used to detect the physical health of the subject within the range of conventional values, or as a reference for better setting of the injected signal.
  • a system and method for measuring the impedance of a skin to a signal by applying a signal of high, medium, and low frequency to the human skin, for detecting the physical health of a subject, and providing the test in real time.
  • the present invention provides a system for injecting a signal of a high, medium, and low frequency into a human skin to measure the impedance of the skin to the signal for detecting the physical health of a subject, which includes:
  • An energy output device having a high, medium, and low frequency comprising:
  • An input device for generating a program with high, medium, and low frequency (low frequency refers to frequency below 1 KHz, mid-frequency refers to frequency between 1 KHz and 100 KHz, and high frequency refers to 100 KHz to 5 MHz)
  • the frequency, waveform, power and pause time of the main wave, and the frequency and waveform of one of the carrier inputs; a programmable logic between the program logic to control the logical combination of the system; a microprocessor, Connected to the input device and the programmable logic, combined with the microprocessor via an application program, for processing the input data and outputting the corresponding programmable frequency, waveform, power and pause of the main wave Time, and the first digit data of the frequency and waveform of the carrier; a programmable main wave and carrier frequency waveform generator connected to the microprocessor, having a set of digital analog converters, two programmable analog switches, And a first low pass filter device having n first filters (n is an integer greater than 0), the set of digital analog converters
  • a programmable output outputter coupled to the programmable power amplifier, inputting the second waveform signal, and converting into an injection signal into the body of the subject by programmably selecting one of the first contact conductive members Part;
  • a measure of the impedance of the skin to the injected signal comprising:
  • a programmable input device is coupled to another portion of the body of the subject by programmably selecting one of the second contact conductive members to form a circuit loop with the injection signal to output a first measure Signal
  • a programmable signal amplifier that inputs the first measurement signal of the programmable input device for amplifying the first measurement signal to output a second measurement signal
  • a second low pass filter device coupled to the programmable signal amplifier having two programmable analog switches and n second filters (n is an integer greater than 0, the same below) for filtering Noise of the second measurement signal to output a third measurement signal;
  • An analog-to-digital converter is coupled to the second low-pass filter device for converting the third measurement signal from the analog signal to a second digital data to be output to the microprocessor to utilize the microprocessor Processing the second digital data;
  • An output device for displaying an output signal processed by the microprocessor which represents an impedance change value (electrical spectrum value) of the body to the injected signal after the subject adds the body to the injection signal, It is used to detect the physical condition of the subject.
  • the output device is also used to display related data input by the input device.
  • the human skin is injected with a signal of high, medium and low frequency to measure the electrical spectrum value of the skin for the signal as a percentage value, which is divided by the impedance value of the injected signal without passing through the human skin.
  • the percentage value of the human skin's impedance value to the injected signal is a signal of high, medium and low frequency to measure the electrical spectrum value of the skin for the signal as a percentage value, which is divided by the impedance value of the injected signal without passing through the human skin.
  • the present invention provides a method for injecting high, medium and low frequency into human skin (low frequency refers to frequency below 1 KHz, mid-frequency refers to frequency between 1 KHz and 100 KHz, and high frequency refers to 100 KHz to 5 MHz)
  • the present invention provides an energy output device having a high, medium, and low frequency, comprising:
  • An input device for generating a programmatically set frequency, waveform, power and pause time of a main wave having a high, medium, and low frequency, and inputting data of one of a frequency and a waveform of the carrier;
  • a programmable logic gate for programming a hardware logic gate to control a logical combination of the system; a microprocessor coupled between the input device and the programmable logic, coupled to the microprocessor via an application program, The first digital data for calculating the frequency, waveform, power and pause time of the programmable main wave and the frequency and waveform of the carrier; and the programmable main wave and the carrier a frequency waveform generator coupled to the microprocessor, having a set of digital analog converters, two first programmable analog switches, and a first low pass filter device having n first filters (n is greater than An integer of 0), the set of digital analog converters is configured to convert the first digital data into an analog frequency, a waveform, a pause time, and a frequency and waveform signal of the main wave, and the first low pass
  • the filter device is configured to filter out the resonance noise of the digital analog converter, and generate a programmable main wave according to the first digital data output by the microprocessor a first waveform signal is outputted by the wave
  • a programmable power amplifier coupled to the programmable main wave and carrier frequency waveform generator for programmably amplifying the power of the first waveform signal to generate a second waveform signal of an appropriate power; and a programmable An output device connected to the programmable power amplifier, inputting the second waveform signal, and converting the injection signal into the received signal by selectively selecting one of the first contact conductive members Test a part of the body.
  • the programmable main wave and carrier frequency waveform generator comprises: a set of digital analog signal converters electrically connected to the microprocessor for generating a first analog signal; a program analog switch, electrically connected to the group of digital analog signal converters, for inputting the first analog signal, the programmable selection generates an nth switching signal;
  • a first low pass filter device electrically coupled to the first programmable analog switch having n first filters, an nth filter for receiving the nth switching signal to generate one of a desired frequency band a filtered signal, wherein preferably the n first filters comprise a first low frequency filter, a first intermediate frequency filter, and a first high frequency filter;
  • a second programmable analog switch is electrically coupled to the first low pass filter means for programmably selecting the input of the nth filtered signal to output a first waveform signal.
  • the energy output device having high, medium, and low frequency preferably further includes a USB interface electrically connected to the microprocessor for connection to an external personal computer for display on the display of the external personal computer.
  • a USB interface electrically connected to the microprocessor for connection to an external personal computer for display on the display of the external personal computer.
  • the present invention provides a system for injecting a signal of a high, medium, and low frequency into a human skin to measure the impedance of the skin to the signal.
  • a skin-to-injection signal of the present invention A measure of impedance, comprising:
  • a programmable input device and programmatically selecting one of the second contact conductive members and connected in series to another portion of the body of the subject, forming a circuit loop with the injection signal, and outputting through the circuit loop a first measurement signal;
  • a programmable signal amplifier the first measurement signal input to the programmable input device, for amplifying the first measurement signal and outputting a second measurement signal;
  • a second low pass filter device coupled to the programmable signal amplifier having two programmable analog switches and n filters (n is an integer greater than 0) for filtering noise of the second measurement signal, To generate a third measurement signal;
  • An analog-to-digital converter connected to the second low-pass filter device for converting the third measurement signal into analog data by a analog signal and outputting the same to the microprocessor to perform the digital data by using the microprocessor Processing;
  • the second low pass filter means comprises:
  • a third programmable analog switch is connected to the programmable signal amplifier for inputting the second measurement signal, and programmable to output an nth programmable signal;
  • n second filter connected to the third programmable analog switch, for inputting the nth programmable signal to generate an nth frequency band signal of a desired frequency band, wherein the n second second filters are preferred a second low frequency filter, a second intermediate frequency filter, and a second high frequency filter, and the first low frequency filter of the first filter of the first filter device
  • An intermediate frequency filter and a first high frequency filter are corresponding and are selectable by a program
  • a fourth programmable analog switch is coupled to the n second filters for programmable input of the nth band signal to output a third metric signal.
  • the system for injecting one of the high, medium, and low frequency signals into the human skin to measure the impedance of the skin to the signal further includes a fixed signal amplifier and an overcurrent detector connected to the programmable input.
  • the overcurrent detector is connected to the fixed signal amplifier, when the current of the amplified first measurement signal exceeds a programmablely set predetermined value or a maximum human safety regulation At the current value, an overcurrent detection signal is output to the output overcurrent safety switch of the programmable output distributor and the input overcurrent safety switch of the programmable input input device, and the programmable output output device is
  • the program distribution input device is turned off, so that the second waveform signal is not injected into the subject, so as to prevent the subject from being damaged by excessive current, and the overcurrent detection signal is also input into the microprocessor through the micro
  • the processor sends an overcurrent detection message to an LED digital display that shows the overcurrent condition.
  • the frequency of the main wave of the high-medium-low-cycle injection signal is programmable at 5 MHz or less.
  • the frequency and waveform of the carrier wave are also It can be set programmatically.
  • the injection signal is applied to a part of the body of the subject, which is a skin, acupuncture or meridian of the human body.
  • the energy output device having high, medium, and low frequency waves further includes a memory connected to the A microprocessor for storing data of data processed by the microprocessor and programs of the system itself.
  • the memory is a flash memory (ROM) or a static memory (SRAM).
  • the input device is a key combination.
  • the output device is an LED digital display.
  • the first contact conductive member is a conductive patch, a metal pedal, a metal grip bar or a hand grip bar.
  • the first contact conductive member further comprises a detecting disk electrically connected to the programmable output distributor for electrically transmitting a message of a substance (such as a drug or the like) carried thereon to the The output can be programmatically assigned.
  • a substance such as a drug or the like
  • the second contact conductive member is a conductive patch, a metal pedal, a metal hand grip, or a hand detecting probe, and the hand detecting probe is controlled by a detector (or The tester himself is to measure the probe of the subject's measurement point.
  • the main wave of the first waveform signal can be a sine wave, a square wave, a triangular wave or other waveform and the waveform of the carrier can also be programmed.
  • the system for injecting one of the high, medium and low frequency signals to the human skin to measure the impedance of the skin to the signal is used to detect the health of the body by the human current safety value.
  • the invention further provides a method for injecting a signal of high, medium and low frequency into human skin to measure the impedance of the skin to the signal, as a method for detecting physical health, comprising the following steps:
  • the signal of the high, medium, and low frequency is injected into a part of the human skin of a subject via a programmable selection of a first contact conductive member (preferably a hand detecting bar)
  • a first contact conductive member preferably a hand detecting bar
  • the human skin is injected with a signal of high, medium and low frequency to measure the electrical spectrum value of the skin for the signal as a percentage value, and the percentage value is the impedance value of the injected signal without passing through the human skin. Divided by the percentage value of the impedance value of the injected signal through the human skin.
  • the first contact conductive member is a conductive patch, a metal pedal, a metal hand grip, or a hand test bar
  • the second contact conductive member is a conductive patch and a metal pedal. ⁇ , metal hand grip, or hand grip detection probe.
  • the frequency of the main wave of the high, medium, and low frequency injection signal is below 5 MHz.
  • the other part of the human skin is the skin, acupuncture or meridian of the human body, which is a measurement site (measurement point) for measuring the health of the relevant organ.
  • each has its own corresponding injection signal according to the method of the present invention, wherein the frequency, waveform, power and pause of the main wave of the high, medium and low frequency injection signal Time, and the frequency and waveform of its carrier, can be programmed to adjust to different organ degradation (diseases) or different infectious diseases, with better corresponding measurement of the injected signal, so that the measurement signal is compared Good signal/noise ratio (S/N value), ⁇ Obtain accurate electrical spectrum value, so the measured electrical spectrum value can more accurately provide the subject's related organ degradation (disease) or infectious disease Interpretation of health status.
  • S/N value Good signal/noise ratio
  • the injection signal of the corresponding corresponding measure is set to a square wave with a frequency of 10.0 Hz, a pause time of 0 seconds, a carrier frequency of 200 Hz sine wave, power
  • the size is the main wave amplitude of 1.0V.
  • the other part of the body is located in the liver organ for detection, and the measurement points are the inner side of the thumb of the left and right feet.
  • the health condition of the related organ includes an inflammatory condition, a normal condition, a degraded condition, and a severely degraded condition.
  • a system and method for measuring the impedance of a skin to a signal by injecting one of a high, medium, and low frequency signal to a human skin for detecting a health condition of the body, wherein the electrical spectrum value is not through human skin
  • the impedance value of the injected signal ie, the injected signal directly outputted without the human skin is short-circuited with the input first measurement signal, as shown in FIG. 2, the switch S in the program-distributable outputter 204 can be directly short-circuited. Closed) divided by the percentage value of the impedance value of the injected signal through the human skin.
  • a related organ such as a liver organ, has a range of health and electrical spectrum values as shown in Table 1 below:
  • the electrical spectrum values of the table 1 may also be in different ranges.
  • the electrical spectrum value may also be set by different percentage values (different magnifications have different electrical spectrum values, such as the electrical spectral value below the three percentage value
  • the three-fold electrical spectrum value of the percentage value is a different value.
  • the electrical spectral values within the invention are referred to as percentage values.
  • Figure 1 is a schematic illustration of a system for injecting a high, medium, and low frequency signal into a human skin to measure the impedance of the skin to the signal.
  • Figure 2 is a circuit block diagram of a system for injecting a high, medium, and low frequency signal into a human skin to measure the impedance of the skin to the signal.
  • Figure 3 is a schematic illustration of the injection signal (frequency, waveform, pause time, power, and carrier thereof) of the injected signal or a therapeutic wave of the present invention.
  • FIG. 4 is a schematic diagram of a carrier on the main wave of the injection signal of the present invention.
  • Microprocessor 201 Measuring device for the impedance of the skin to the injected signal 2002 Microprocessor 201
  • Input overcurrent safety switch 2052 Fixed signal amplifier 20521 programmable signal amplifier 206 second measurement signal 2061
  • Second low pass filter device 207 third measurement signal 2071
  • Second low frequency filter 20721 first frequency band signal 207211 second intermediate frequency filter 20722 second frequency band signal 207221 second high frequency filter 20723 third frequency band signal 207231 third programmable analog switch 2073 first programmable measuring signal 20731 second Programmable measurement signal 20732 third programmable measurement signal 20733 fourth programmable analog switch 2074 over current detector 208
  • Second contact conductive member 2004 conductive patch ⁇ , ⁇ 2 , , ⁇ 3 ' , ⁇ 4 , metal hand grip ⁇ , ⁇ 2 ' metal pedal ⁇ CI ' , C2 ' hand detection probe El Subject 3
  • human health and unhealth in the present invention is "normally measured” in the theory of Chinese and Western medicine, that is, if the physiological value of the human body of the subject falls within the range of the normal value of the human body (normal state), the human body is in a healthy state. On the contrary, if the physiological data of the human body falls outside the range of the normal value (extreme state), the human body is in an unhealthy condition (lesion).
  • the blood routine examination of Western medicine, GOT, GPT is the main distinguishing item for examining liver diseases, among which The GOT conventional value is below 37 K units/ml and the GPT conventional value is below 42 K units/ml. If the two are not within the normal value range, the liver of the subject is discriminated according to the normal measurement.
  • Unhealthy conditions must be traced to the health of the subject's liver; as in Chinese medicine to diagnose the disease, the normal (healthy) pulse is called Pingmai, others such as floating veins, Shen Pulses, pulses, and delayed veins are all abnormal blood vessels. According to this (using constant measurement), they are identified as various unhealthy conditions of the body.
  • a system and method for measuring the impedance of the skin to the signal by injecting a signal of high, medium, and low frequency to the human skin, as shown in Table 1, if the electrical spectrum value falls within the conventional value of the human body. Within the range, it is in a normal condition (health condition); conversely, if the electrical spectrum value falls outside the range of the normal value, it is in an abnormal condition (unhealthy condition).
  • FIG. 1 is a schematic diagram of a system for injecting high-medium and low-frequency signals into human skin to measure the impedance of the skin to the signal
  • FIG. 2 is a view of the human skin of the present invention.
  • a circuit block diagram of a system 200 (100 of FIG. 1) that injects one of the high, medium, and low frequency signals to measure the impedance of the skin to the signal, and the system that injects high, medium, and low frequency signals into the human skin to measure the impedance of the skin to the signal.
  • 100 has a body 101.
  • the body 101 is electrically connected to the outside to programably select a conductive patch A1, A2, A3, A4, a metal hand grip B1, B2, a metal pedal C1, C2, and a first contact conductive member 2003.
  • the measuring system of the present invention for detecting the health of a liver organ, as shown in FIG. 2, the system provides a signal of a high, medium, and low frequency, and the subject holds the first contact conductive member 2003.
  • the hand holds the detecting rod F1, whereby the signal of the high, medium and low frequency is converted into an injection signal, injected into a part of the body of the subject 3, and a detecting person
  • the detecting probe E1 holding the second contact conductive member 2004 contacts the relevant measuring portion (measurement point) of the relevant organ of the subject (for example, detecting the liver organ measuring point for the inner side of the thumb of the left and right feet of the human body) a portion to form a circuit loop that can be displayed on an LED display 2012, the electrical spectrum value being non-human skin (the injection signal is in an unloaded state, ie, directly to the human skin without the human skin)
  • the waveform signal 2031 is directly programmable by the switch S of the programmable output outputter 204 to directly close the first measurement signal 2051 at the rear end of the programmable input device 205.
  • the impedance value of the injected signal is divided by the human body.
  • the skin (the injected signal is in a loaded state as shown in Figure 2 follows the detected circuit path) as a percentage of the impedance value of the injected signal.
  • the high-medium-low-frequency energy output device further includes a USB interface 1021 electrically connected to the microprocessor 201 for providing connection to an external personal computer 102 (for example, a personal computer, a notebook computer, etc.) to The storage and operation of a measurement result and a related measurement data are displayed on the display of the computer.
  • FIG. 2 is a circuit block diagram of a system 200 (100 of FIG. 1) for injecting a signal of high, medium, and low frequency into human skin to measure the impedance of the skin to the signal, having a high, medium, and low
  • the energy output device 2001 of Zhou Bo and a measuring device 2002 for the impedance of the skin to the injected signal, the high-, low-frequency energy output device 2001 includes a microprocessor 201.
  • the system 200 further includes: a button combination 2011 electrically connected to the microprocessor 201 for generating an input setting related frequency, waveform, power and pause time of the main wave of the high, medium and low frequency, and the frequency and waveform of the carrier thereof Related data, the input waveform can be sine wave, square wave, triangle wave, trapezoidal wave, or other waveforms of various shapes; when inputting other irregular shape waveforms, only the irregular waveform needs to be correlated
  • the waveform data input can be performed; an LED digital display 2012 is electrically connected to the microprocessor 201, and is used for displaying the measurement value (electrical spectrum value) of the measurement system and the related data input by the button combination 2011;
  • the program logic gate 2013 is electrically connected to the microprocessor 201 for programming hardware logic to control a logical combination of the device system hardware; a memory 2014 is electrically connected to the microprocessor 201 for storing and storing the microprocessor Processing data and program data.
  • the high-medium-low-cycle energy output device 2001 includes a programmable main wave and carrier frequency waveform generator 202 for outputting the frequency, waveform, and pause time of the main wave according to the microprocessor, and the frequency of the carrier thereof.
  • a first digital data 20 related to the waveform generates a first waveform signal 2023, which includes a set of digital analog converters 2021 and a first low pass filter device 2022.
  • the set of digital analog converters 2021 is used for the first
  • the digital data 2015 is converted into a first analog signal, and the first analog signal is passed through the first low pass filter device 2022 to filter out the harmonic of the digital analog converter 2021.
  • the first waveform signal 2023 is outputted by a high, medium, and low frequency. Among them, the low frequency is below 1 KHz, the mid-cycle frequency is 1 KHz to 100 KHz, and the high frequency is 100 KHz to 5 MHz.
  • the programmable main wave and carrier frequency waveform generator 202 includes:
  • a set of digital analog signal converters 2021 are electrically connected to the microprocessor 201 for generating a first analog signal 20211;
  • a first programmable analog switch 2024 is electrically coupled to the set of digital analog signal converters 2021 for inputting the first analog signal 20211 to programmatically select an output of an nth switching signal 20241, 20242, 20243 (n is greater than An integer of 0);
  • the first programmable analog switch 2024 is electrically coupled to a first through nth filter 20221, 20222, 20223, and the nth filter 20221, 20222, 20223 is used for inputting a corresponding The nth switching signal 20241, 20242, 20243 is configured to generate an nth filtered signal 202211, 202221, 202231;
  • a second programmable analog switch 2025 is electrically connected to the first low pass filter device 2022 and controlled by the microprocessor 201 for inputting the corresponding nth filtered signals 202211, 202221, 202231 to output the first A waveform signal 2023.
  • the nth filters 20221, 20222, and 20223 are a first low frequency filter 20221, a first intermediate frequency filter 20222, and a first high frequency filter 20223, respectively.
  • the first waveform signal 2023 is input to a programmable power amplifier 203 to programmably amplify (also attenuate) the power of the first waveform signal 2023 within a safe range of the system power supply voltage to generate a first
  • the two waveform signals 2031 are electrically coupled to the programmable main wave and carrier frequency waveform generator 202.
  • the second waveform signal 2031 is input to a programmable output outputter 204, and is electrically connected to the selected one of the first contact conductive members 2003 via a programmable selection of the programmable output output unit 204 for converting the second waveform signal 2031.
  • the second waveform signal 2031 is injected into the signal 2041 (the injection signal for checking the physical health condition of the subject or the therapeutic radio wave for treating the disease or pain by the user), for example: a subject 3 to the conductive patch A1 Pressing on a part of the subject's 3 hands, the other hand of the subject 3 (or another tester) holds the hand gripper El to contact the subject 3
  • the relevant measurement site (measurement point) of the organ is such that a loop signal 31 is generated to flow through the body of the subject 3, and the injection signal outputted by the device is injected into the body of the subject 3 in series.
  • the loop signal 31 is input to the system via the selected one of the second contact conductive members 2004.
  • One of the skin measuring devices 2002 for the impedance of the injected signal can program the input device 205 from which a first measurement signal 2051 is output.
  • the first measurement signal 2051 is input to a fixed signal amplifier 20521, and the fixed signal amplifier 20521 is connected to the programmable input device 205 for amplifying the first measurement signal 2051, and an overcurrent detector 208 is connected to The fixed signal amplifier 20521, after the first measurement signal 2051 is amplified by the fixed signal amplifier 20511, is output to the overcurrent detector 208 for comparing and detecting the first measurement signal, if the current of the first measurement signal exceeds
  • an overcurrent detection signal A 2081 is output to the output overcurrent safety switch 2042 in the programmable output distributor 204 and the programmable assignable
  • the input overcurrent safety switch 2052 in the input device 205 closes the string programmable distribution outputter 204 and the programmable input transducer 205, so that the second waveform signal is not injected into the subject, in case The subject is subjected to excessive current damage, and the overcurrent detection signal 2081 is simultaneously input to the
  • the output overcurrent safety switch 2042 in the programmable distribution outputter 204 or/and the input overcurrent safety switch 2052 in the programmable input 205 is not cut off. The measurement check continues.
  • the first measurement signal 2051 is input to a programmable signal amplifier 206, and the first measurement signal 2051 is amplified to output a second measurement signal 2061.
  • the second measurement signal 2061 is input to a third programmable analog switch 2073.
  • the second low-pass filter device 207 inputs a fourth programmable signal 2074, generates a third measurement signal 2071, inputs the analog signal to the analog converter 209, and outputs a second digital data 2091.
  • the data processing of the microprocessor 201 is based on the unloaded second digital data (ie, the second waveform signal 2031 via
  • the selection switch S of the programmable distribution outputter 204 can be directly short-circuited and then electrically connected to the output of the programmable input device 205 to become the first measurement signal 2051, and then converted by signal processing and analog digital signal conversion.
  • the second digital data 2091 generated by the conversion of the device 209 that is, the second digital data generated by the circuit loop of the human body of the subject
  • the percentage value (electrical spectrum value) of the second digit data (the second digit data generated by the circuit loop of the subject's human body) is output to the LED digital display 2012 for display
  • the value of the impedance change (indicated by the percentage value, also known as the electrical spectrum value) of the body skin after the signal of the high, low, and low frequency is injected into the subject.
  • the second low pass filter means 207 comprises:
  • a third programmable analog switch 2073 is coupled to the programmable signal amplifier 206 for inputting the second measurement signal 2061 to generate a first to nth programmable signal 20731, 20732, 20733;
  • the n second low-pass filters 20721, 20722, 20723 are connected to the third programmable analog switch 2073 for receiving the n-th programmable signal 20731, 20732, 20733 to generate an n-th band signal 207211, 207221 , 207231 ; and
  • a fourth programmable analog switch 2074 is coupled to the n filters 20721, 20722, and 20723 for receiving the nth band signals 207211, 207221, and 207231, and outputs the third metric signal 2071.
  • the nth second low pass filter 20721, 20722, 20723 is a second low frequency filter 20721, a second intermediate frequency filter 20722, and a second high frequency filter 20723, respectively.
  • the operation of the corresponding frequency band corresponds to the first low frequency filter 20221, the first intermediate frequency filter 20222 and the first high frequency filter 20223 of the first low pass filter device 2022 in the program selection operation. Frequency band relationship.
  • FIG. 3 is the injection signal 2041 of the present invention.
  • FIG. 1 A schematic diagram of the injection signal for examining the physical health condition of the subject or the therapeutic radio wave for treating the disease or pain by the user), wherein the two adjacent waveforms are pause time t2, and the time occupied by the waveform is tl Where the horizontal axis is time and the vertical axis is amplitude (voltage value).
  • FIG. 4 is one of the waveforms of the main wave and its carrier wave of the injection signal 2041 (the injection signal for checking the physical health condition of the subject or the therapeutic radio wave for treating the disease or pain of the user) of the present invention.
  • the carrier frequency and waveform can be programmed (the general carrier frequency is not less than 10 times the main wave frequency), wherein the waveform of the two adjacent main waves is the pause time t4, and the time occupied by the main waveform is t3.
  • the horizontal axis is time and the vertical axis is amplitude (voltage value).
  • the conventional general high, medium and low frequency therapeutic apparatus has a carrier-free programmable function of setting its frequency and waveform, and the main wave is also unprogrammable.
  • the therapeutic apparatus significantly affects the effect of the treatment.
  • the present invention provides an energy output device having a high, medium, and low frequency, the frequency, waveform, power, and pause time of the main wave output by the device, and
  • the frequency and waveform of the carrier can be programmed in a safely specified value to output an injection signal (as the injection signal for the subject to check the physical health condition or the treatment wave for the user to treat the disease or pain) , can solve the above-mentioned lack of the traditional high school and low frequency therapeutic apparatus, and significantly increase the therapeutic effect. .
  • a device for measuring the impedance of the skin-injection signal of the present invention - a radio wave for injecting high, medium, and low-cycle energy into the human skin for treatment can be obtained by the measuring device of the present invention, Digitize, store, process, and output the electrical spectrum value to the display, allowing a user to inject the high, medium, and low frequency of the injected signal with the frequency, waveform, power, pause time, and the frequency of the carrier, and the waveform due to the electrical spectrum.
  • the reading value of the value is used as a reference for the preferred output setting value.
  • the preferred therapeutic effect means that the electrical spectrum value tends to be closer to the conventional value range when the user is treated with high, medium or low frequency or after treatment.
  • the design of the measuring device with the electrical spectrum value makes the high-middle and low-frequency treatment achieve better results.
  • the human skin measures the change of DC resistance to detect the health of the body.
  • the Japanese good guide system can only provide the non-real-time physical health status of the subject at a certain time (how long is uncertain).
  • the message does not provide real-time information about the subject's related infectious diseases, related organ degradation (diseases) and related tumors.
  • the present invention provides a measurement system and method for measuring changes in signal impedance of human skin (such as human body meridians, acupoints, etc.) injected into various frequencies and waveforms for detecting physical health. It provides real-time information on the relevant infectious diseases, related organ degradation (diseases) and related tumors of the subjects, and is a highly progressive system and method for measuring physical health.
  • the system of the present invention (1) can be used to set the square wave of the injection signal as the main wave at a frequency of 8.5 Hz, pause time For 0 seconds, the carrier frequency is a sine wave of 170 Hz, and the power level is 1.0V for the main wave amplitude.
  • the relevant measurement points are the index finger parts of the left and right hands, and the electrical spectrum value ⁇ is 60 or more (inflammation).
  • the medical profession has not found a device that allows physicians to treat patients with medication, surgery, chemotherapy, radiotherapy, etc., and has a simple, rapid, non-invasive measurement system and method that can provide physicians with
  • the present invention provides a metric system and method for the lack of real-time information on the effect and overall impact of the patient after treatment, as described in the present invention , can be used to detect physical health, provide real-time information about the subject's related infectious diseases, related organ degradation (disease) and related tumors, and thus provide a simple, rapid, non-invasive measurement system for physicians.
  • a real-time information on the effect and overall impact of the patient for example, after a physician treats a patient, etc., by using the measurement system, measuring the electrical spectrum value of the measurement point of the relevant organ of the patient, Whether the electrical spectrum value tends to change within the range of conventional values, according to which the physician can obtain the disease simply, quickly, and non-invasively.
  • the treatment After the treatment, its real-time message and overall impact of the effect, and as the next treatment drug reference.
  • Another object of the present invention is a system for injecting a signal of a high, medium, and low frequency into a human skin to measure the impedance of the signal as a check for the physical condition of the subject.
  • human skin has its own correspondingly measurable injection signal for various organ degradation (diseases) and different infectious diseases.
  • the invention outputs a high, medium and low frequency, the frequency, waveform, power and pause time of the main wave of the injection signal, and the frequency and waveform of the carrier and the waveform can provide the user within the safety specified value (individual, patient, doctor, researcher)
  • the system can adjust the settings programmatically to obtain the best signal/noise ratio of the measurement signal.
  • the thus detected electrical spectrum value can more accurately provide the subject's related organ degradation (disease) and correlation. Interpretation of the health status of infectious diseases.
  • the energy output device having high, medium and low frequency includes a detecting plate D1, a conductive metal piece or a conductive container (isolated from the outside), and electrically connected to the programmable output outputter 204.
  • the purpose is to detect the information of the substance (such as medicine) placed on the disc D1 (the equivalent of the material can affect the impedance value of the loop), and programmatically set whether the test disc is connected to
  • the second waveform signal 2031 detects whether the information of the substance (such as a medicine, etc.) placed on the disc D1 affects the electrical spectrum value of the subject, and is known by the measuring system to provide the subject with the relevant substance (
  • the substance on which the disc is placed is a positive or negative impact assessment.
  • the high-medium-low-cycle injection into the human body has a low voltage value, the current injected into the human body is very small, but when the human body forms a resonance with a certain frequency wave, the human skin impedance Z becomes very Low to As for causing a great current to be injected into the human body and causing damage.
  • the present invention is configured by the output overcurrent safety switch 2042 and the input overcurrent safety switch 2052 (shown in FIG.
  • the first measurement signal 2051 of the human body is amplified by the fixed signal amplifier 20521 and then input to the overcurrent detector 208.
  • an overcurrent detection signal 2081 is output to the output overcurrent safety switch 2042 of the programmable output distributor 204, and
  • the programmable over-current safety switch of the input device 205 is configured to simultaneously close the 2052 of the programmable output output device and the programmable input device, so that the second waveform signal is not injected into the subject 3,
  • the overcurrent detection signal is also input to the microprocessor 201, and an overcurrent detection message is sent through the microprocessor 201.
  • the LED digital display 2012 displays an overcurrent condition. .
  • a system and method for injecting a signal of a high, medium, and low frequency into a human skin to measure the impedance of the skin to the signal wherein the human skin is injected with a signal of high, medium, and low frequency to measure the impedance of the skin to the signal.
  • the system is used to assess the physical health of a subject, a specific example, for example, to check the health of a subject's liver organs:
  • the injection signal injected into the human body by (1) of the system of the present invention can be set as a square wave having a frequency of 10.0 Hz as a main wave, a pause time of 0 seconds, and a carrier wave having a frequency of 200 Hz.
  • the power level is 1.0 V for the main wave vibration;
  • the measurement points of the liver organs are the thumb of the left and right feet, and the electrical spectrum values of the relevant measurement points, wherein any of the electrical spectrum values fall in a severely degraded condition ( Abnormal condition) (Electrical spectrum values 0 to 20, as shown in Table 1), as an assessment of unhealthy (abnormal conditions) of liver disease.
  • the injection signal injected into the human body by the system of the present invention is set as a square wave having a frequency of 10 Hz as a main wave, and the pause time is 0 seconds.
  • the sine wave with a frequency of 200 Hz, the power level is 1.0 V for the main wave vibration.
  • the tester holds the test stick Fl by the left or right hand of the subject, and the tester's hand (left or right hand) can hold the detection probe El.
  • To measure the inner part of the thumb of the subject's left and right feet obtain the electrical spectrum value of the right foot measurement point 48 (normal condition), and the electrical spectrum value of the measurement point of the left foot.
  • liver organ degeneration Disease
  • statistical results can be used to detect that the subject's liver organ is in an unhealthy condition (abnormal condition).

Landscapes

  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Medical Informatics (AREA)
  • Physics & Mathematics (AREA)
  • Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
  • Biophysics (AREA)
  • Pathology (AREA)
  • Dermatology (AREA)
  • Biomedical Technology (AREA)
  • Heart & Thoracic Surgery (AREA)
  • Radiology & Medical Imaging (AREA)
  • Molecular Biology (AREA)
  • Surgery (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Public Health (AREA)
  • Veterinary Medicine (AREA)
  • Measurement And Recording Of Electrical Phenomena And Electrical Characteristics Of The Living Body (AREA)

Abstract

一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的阻抗之系统与方法,及关于一种输出高中低周波之一注入讯号,其主波之频率、波形、功率与暂停时间,及其载波之频率与波形在安全规定值内能可程序化地设定输出,以串接注入于人体皮肤、并经由量度讯号的撷取与处理,据以量度人体皮肤(如人体的经络、穴位等)对该注入讯号的阻抗变化值(简称电频谱值),用以(1)作为身体健康状况检测之系统与方法,及(2)作为高中低周波该注入讯号的较佳设定值之参考。

Description

说 明 书 量度皮肤阻抗之系统与方法 技术领域
本发明关于一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统与方法, 尤指一种输出高中低周波之一注入讯号, 其主波之频率、 波形、功率与暂停时间, 及其载波之频率与波形在安全规定值内能可程序化地设 定输出, 以串接注入于人体皮肤、 并经由量度讯号的撷取与处理, 据以量度人体 皮肤 (如人体的经络、 穴位等)对该注入讯号的阻抗变化值 (简称电频谱值), 用以 (1M乍为身体健康状况检测之系统与方法, 及 (2)作为高中低周波该注入讯号的较 佳设定值之参考。
背景技术
高中低周波治疗仪可以治疗身体的疼痛, 中西医界行之有年, 决定仪器疗效 是以波形、频率、暂停时间与功率为主要输出物理量, 传统的一般高中低周波治 疗仪有下列缺点: (a)传统的一般高中低周波治疗仪的功率,只能简单地调整功率, 无法由可程序地设定; (b)对传统的治疗仪的频率, 一般只提供使用者仅有几个 频率可以选择, 无法由可程序化地设定; (c)对于传统输出的波形, 一般只有几个 固定波形可供选定, 无法让使用者能可程序化地设定; (dM专统输出功率一般为 连续性的波形输出或为几个选择性的暂停时间,波与波之间暂停时间无法程序化 地设定; 及 (e)传统输出的波形无载波频率及波形可予以程序化地设定。
传统的高中低周波治疗仪没有结合皮肤对高中低周波注入讯号的阻抗的量 度设计, 故传统者另有下列缺点: (1)传统的高中低周波治疗仪没有注入讯号的 阻抗变化值的量度设计,故传统的高中低周波治疗仪无法提供使用者作为仪器输 出之频率、 波形、 功率、 暂停时间作较佳设定值 (系指经高中低周波治疗后其电 频谱值趋向落于常规值范围内)的参考,据以得到高中低周波治疗仪较佳的疗效; (2)传统现有的量度皮肤对注入电波阻抗变化的装置, 仅只停留在对人体一注入 直流电作阻抗变化的量度, 该注入直流电对皮肤阻抗变化之量度装置, 无法对施 加于人体非直流的频率、 波形讯号的阻抗变化作量度。
人体皮肤对注入直流电阻抗变化的量度是目前公认可得知身体健康状况检 测的一种方法, 行之有年, 如日本良导络系统、 西德 Dr. VoLL系统等。 但对人 体皮肤注入高中低周波 (非直流电)讯号的阻抗变化值之量度系统作为身体健康 状况的检测系统与方法及其应用目前尚未有之。
人体皮肤对加注直流电阻抗变化的量度用于检测身体健康状况,如日本良导 络系统等, 仅能提供受测者在最近某一段时间 (多长时间不可确定)的非实时性的 身体健康状况讯息,无法实时性地提供受测者相关的传染性疾病、相关的器官退 化和相关的肿瘤的讯息。
针对上述现有技术之缺失,本发明提供一量度系统与方法, 用以量度人体皮 肤 (如人体的经络、穴位等)对注入各种频率及波形讯号的阻抗变化值 (电频谱值), 用来检测身体健康状况, 可实时性地提供受测者的相关传染性疾病、相关器官退 化和相关肿瘤的讯息。
发明内容
本发明系有关一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统及方法。 本发明之系统包括:
一具有高中低周波之能量输出装置, 用于产生一高中低周波之一注入讯号, 以施加该注入讯号于一受测者或一使用者身体的一部份,作为该受测者检查身体 健康状况之该注入讯号或该使用者治疗疾病或疼痛用的一治疗电波之装置; 及 一皮肤对注入讯号的阻抗之量度装置, 连接至该受测者身体的另一部份,与 该受测者身体的该注入讯号形成一电路回路, 并经由该电路回路输出一量度讯 号, 用于量度该受测者之皮肤对于该注入讯号阻抗变化值 (电频谱值), 依照该电 频谱值是否落于常规值范围内,用来检测出该受测者之身体健康状况, 或作为该 注入讯号的较佳设定值参考。
依据本发明之一种对人体皮肤加注高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统与方法,用来检测一受测者之身体健康状况, 可实时性地提供该 受测者相关的传染性疾病、 相关的器官退化和相关的肿瘤的讯息。
根据本发明的另一目的,本发明提供一种对人体皮肤注入高中低周波之一讯 号以量度皮肤对该讯号的阻抗之系统,用于检测一受测者之身体健康状况, 其包 括:
一具有高中低周波之能量输出装置, 其包括:
一输入装置,用以产生可程序化设定之具高中低周波 (低周波指频率在 1 KHz以下, 中周波指频率在 1 KHz〜100 KHz, 高周波指 100 KHz〜5 MHz)的一 主波之频率、 波形、 功率与暂停时间, 及其载波之频率与波形之一输入资料; 一可程序逻辑间, 用以程序规划硬件逻辑间以控制该系统的逻辑组合; 一微处理器,连接至该输入装置及该可程序逻辑间, 经由一运用程序与 该微处理器的结合,用于运算处理该输入资料并输出对应的可程序化的该主波之 频率、 波形、 功率与暂停时间, 及其载波之频率与波形之一第一数位资料; 一可程序主波与载波频率波形产生器,连接至该微处理器, 具有一组数 位类比转换器, 两个可程序类比开关, 及一第一低通滤波器装置, 具有 n个第一 滤波器 (n为大于 0之整数), 该组数位类比转换器用以将该第一数位资料转换成 类比的该主波之频率、 波形、 与暂停时间, 及其载波之频率与波形的讯号, 而该 第一低通滤波器装置用以滤除数位类比转换器的谐振噪声,用于根据该微处理器 输出的该第一数位资料产生一可程序化的该主波的波形、频率、 暂停时间, 及其 载波的频率和波形而输出一第一波形讯号,该两个可程序类比开关分别连接于该 第一低通滤波器装置之两侧, 用以可程序化地配合选择一个所需频带之滤波器; 一可程序功率放大器, 连接至该可程序主波与载波频率波形产生器,用 于将该第一波形讯号的功率可程序放大而产生一具适当功率的一第二波形讯号; 及
一可程序分配输出器,连接至该可程序功率放大器, 输入该第二波形讯号, 并通过可程序化地选择之一第一接触导电构件而转换成一注入讯号注入至该受 测者身体的一部份; 以及
一皮肤对注入讯号的阻抗之量度装置, 其包括:
一可程序分配输入器,与通过可程序化地选择之一第二接触导电构件而 串接于该受测者身体之另一部份,与该注入讯号形成一电路回路而输出一第一量 度讯号;
一可程序量度讯号放大器, 输入该可程序分配输入器之该第一量度讯 号, 用于将该第一量度讯号放大后输出一第二量度讯号;
一第二低通滤波器装置,连接至该可程序量度讯号放大器, 其具有两个 可程序类比开关与 n个一第二滤波器 (n为大于 0之整数, 以下同), 用于过滤该 第二量度讯号之噪声, 以输出一第三量度讯号; 及
一类比数位转换器,连接至该第二低通滤波器装置, 用于将该第三量度 讯号由类比讯号转换成一第二数位资料而输出至该微处理器,以利用该微处理器 进行该第二数位资料之处理; 及
一输出装置,用以显示该微处理器所处理结果之一输出讯号, 其代表该 受测者对该注入讯号加注该身体后, 身体对该注入讯号的阻抗变化值 (电频谱 值), 用来检测该受测者的身体健康状况。 该输出装置亦用以显示由该输入装置 所输入的相关资料。
根据本发明,该对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的 电频谱值为一百分比值,该百分比值系以不经由该人体皮肤对该注入讯号的阻抗 值除以经由该人体皮肤对该注入讯号的阻抗值之百分比值。
根据本发明的另一目的, 本发明所提供一种对人体皮肤注入高中低周波 (低 周波指频率在 1 KHz以下, 中周波指频率在 1 KHz〜100 KHz, 高周波指 100 KHz〜5 MHz)之一讯号以量度皮肤对该讯号的阻抗之系统中,本发明提供一种具 有高中低周波之能量输出装置, 其包括:
一输入装置, 用以产生可程序化地设定之具高中低周波的一主波之频率、波 形、 功率与暂停时间, 及其载波之频率与波形之一输入资料;
一可程序逻辑闸, 用以程序规划硬件逻辑闸以控制该系统的逻辑组合; 一微处理器,连接至该输入装置及该可程序逻辑间, 经由一运用程序与该微 处理器的结合,用于运算处理该输入数位资料并输出对应的可程序化的一主波之 频率、 波形、 功率与暂停时间, 及其载波之频率与波形之一第一数位资料; 一可程序主波与载波频率波形产生器,连接至该微处理器, 具有一组数位类 比转换器, 两个第一可程序类比开关, 及一第一低通滤波器装置, 具有 n个第一 滤波器 (n为大于 0之整数), 该组数位类比转换器用以将该第一数位资料转换成 类比的该主波之频率、 波形、 与暂停时间, 及其载波之频率与波形的讯号, 而该 第一低通滤波器装置用以滤除数位类比转换器的谐振噪声,用于根据该微处理器 输出的该第一数位资料产生一可程序化的该主波的波形、频率、 暂停时间, 及其 载波的频率和波形而输出一第一波形讯号,其中该两个第一可程序类比开关分别 连接至该第一滤波器之两端, 用以可程序地选择所需之频带之滤波器;
一可程序功率放大器,连接至该可程序主波与载波频率波形产生器, 用于将 该第一波形讯号的功率可程序放大而产生一具适当功率的第二波形讯号; 及 一可程序分配输出器, 连接至该可程序功率放大器, 输入该第二波形讯号, 并通过可程序化地选择之一第一接触导电构件而转换成该注入讯号注入至该受 测者身体的一部份。 根据本发明, 较佳地该可程序主波与载波频率波形产生器包括有: 一组数位类比讯号转换器,电连接至该微处理器,用于产生一第一类比讯号; 一第一可程序类比开关, 电连接至该组数位类比讯号转换器, 用于输入该第 一类比讯号后可程序的选择产生一第 n开关讯号;
一第一低通滤波器装置, 电连接至该第一可程序类比开关, 其具有 n个第一 滤波器,一第 n滤波器用于接收该第 n开关讯号以产生所需频带之一第 n滤波讯 号,其中较佳者为该 n个第一滤波器包含一第一低频滤波器、一第一中频滤波器、 以及一第一高频滤波器; 及
一第二可程序类比开关, 电连接至该第一低通滤波器装置, 用于可程序的选 择输入该第 n滤波讯号以输出一第一波形讯号。
根据本发明,该具有高中低周波之能量输出装置较佳地另包括一 USB界面, 电连接至该微处理器,用于连接至一外部个人计算机, 用以于该外部个人计算机 之显示器上显示一量测结果与相关量测资料之储存与运用。
根据本发明的另一目的,本发明所提供一种对人体皮肤注入高中低周波之一 讯号以量度皮肤对该讯号的阻抗之系统中, 依据本发明, 本发明的一种皮肤对注 入讯号的阻抗之量度装置, 其包括:
一可程序分配输入器,与可程序化地选择之一第二接触导电构件而串接于该 受测者身体之另一部份, 与该注入讯号形成一电路回路, 并经由该电路回路输出 一第一量度讯号;
一可程序量度讯号放大器, 输入该可程序分配输入器之该第一量度讯号,用 于将该第一量度讯号放大后输出一第二量度讯号;
一第二低通滤波器装置,连接至该可程序量度讯号放大器, 其具有两可程序 类比开关与 n个滤波器 (n为大于 0之整数), 用于过滤该第二量度讯号之噪声, 以产生一第三量度讯号;
一类比数位转换器,连接至该第二低通滤波器装置, 用于将该第三量度讯号 由类比讯号转换成一数位资料而输出至该微处理器,以利用该微处理器进行该数 位资料之处理; 及
一输出装置,用以显示该微处理器所处理结果之一输出讯号, 其代表该受测 者对该注入讯号加注该身体后, 身体对该注入讯号的阻抗变化值 (电频谱值), 用 来检测该受测者的身体健康状况,其中该电频谱值为一百分比值, 该百分比值系 以不经由该人体皮肤对该注入讯号的阻抗值除以经由该人体皮肤对该注入讯号 的阻抗值之百分比值 (电频谱值)。
根据本发明, 该第二低通滤波器装置包括:
一第三可程序类比开关,连接至该可程序量度讯号放大器, 用于输入该第二 量度讯号, 可程序化选择输出一第 n可程序讯号;
n个第二滤波器, 连接至该第三可程序类比开关, 用于输入该第 n可程序讯 号而产生所需频带之一第 n频带讯号,其中较佳者为该 n个第二滤波器包含一第 二低频滤波器、 一第二中频滤波器、 以及一第二高频滤波器, 而其运作系与该第 一滤波器装置之 n个第一滤波器之第一低频滤波器、第一中频滤波器以及第一高 频滤波器相对应且可由程序选定; 及
一第四可程序类比开关,连接至该 n个第二滤波器, 用于可程序化选择输入 该第 n频带讯号, 以输出一第三量度讯号。
根据本发明,该对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的 阻抗之系统另包括一固定讯号放大器及一过电流检知器,该固定讯号放大器连接 至该可程序分配输入器,用以放大该第一量度讯号, 该过电流检知器连接至该固 定讯号放大器,当该放大之第一量度讯号的电流超过一可程序化地设定的预定值 或人体安全规定最大电流值时,则输出一过电流检知讯号至该可程序分配输出器 的输出过电流安全开关与该可程序分配输入器的该输入过电流安全开关而将该 可程序分配输出器与该可程序分配输入器关闭,如此令该第二波形讯号不再注入 该受测者, 以防该受测者过大电流的伤害, 该过电流检知讯号也同时输入该微处 理器, 经由该微处理器送出过电流检知讯息在一 LED数字显示器, 显示过电流 状况。
根据本发明, 该高中低周波之注入讯号的该主波之频率系在 5 MHz以下可 程序化地设定, 较佳地该主波之频率在 100 KHz以下时, 其载波的频率和波形 亦可由程序化地设定。
根据本发明,较佳地该注入讯号加注于该受测者身体的一部份是一人体之皮 肤、 穴道或经络等。
根据本发明, 该具有高中低周波之能量输出装置另包含一存储器, 连接至该 微处理器, 用以记忆该微处理器所处理之数据资料及该系统本身程序的资料。 根据本发明, 较佳地该存储器是快闪存储器 (flash memory, FROM)或静态存 储器 (SRAM)。
根据本发明, 较佳地该输入装置为一按键组合。
根据本发明, 较佳地该输出装置为一 LED数字显示器。
根据本发明, 较佳地该第一接触导电构件是导电贴片、 金属脚踏钣、金属手 握棒或手握检测棒。
根据本发明,较佳地该第一接触导电构件另包含一检测盘, 电连接至该可程 序分配输出器, 用以电连传送一其上所承载之物质 (如药物等)的讯息至该可程序 分配输出器。
根据本发明, 较佳地该第二接触导电构件是导电贴片、 金属脚踏钣、金属手 握棒、 或手握检测探棒, 该手握检测探棒系由一检测者 (或该受测者本人)持以量 测该受测者的量度点之探棒。
根据本发明, 该第一波形讯号之该主波可为一正弦波、 方波、三角波或其他 波形和该载波的波形亦可由程序化地设定。
根据本发明,其中, 该对人体皮肤加注高中低周波之一讯号以量度皮肤对该 讯号的阻抗之系统系在通过人体电流安全值之下用于检测身体健康状况。
本发明另提供一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之方法, 以作为检测身体健康状况的方法, 包括下列步骤:
提供一高中低周波之该讯号将该高中低周波之该讯号经由可程序化选择一 第一接触导电构件 (较佳的为手握检测棒), 注入于一受测者的人体皮肤之一部位 而成一注入讯号, 其中该注入讯号之主波之频率、 波形、 功率与暂停时间, 及其 载波之频率与波形在安全规定内可程序化地设定;
于该第一接触导电构件、该受测者皮肤之一部位及与该受测者皮肤之另一部 位 (量度点)串接至可程序化地选择之一第二接触导电构件 (较佳的为手握检测探 棒)形成一电路回路, 并经由该电路回路输出一量度讯号, 其中该受测者皮肤之 另一部位系受测者相关器官的一相关的量测部位 (量度点);
经由对该量度讯号之撷取、放大与滤除噪声、类比数位转换以及一微处理器 之资料处理, 以产生该受测者相关量度点之一电频谱值; 以及
经由结合该相关器官的量度点和该电频谱值与一常规值之比对以检查该受 测者相关器官之健康状况。
根据本发明之方法,其中该对人体皮肤注入高中低周波之一讯号以量度皮肤 对该讯号的电频谱值为一百分比值,该百分比值系以不经由该人体皮肤对该注入 讯号的阻抗值除以经由该人体皮肤对该注入讯号的阻抗值之百分比值。
根据本发明之方法, 其中该第一接触导电构件为一导电贴片、 金属脚踏钣、 金属手握棒、 或手握检测棒, 该第二接触导电构件为一导电贴片、 金属脚踏钣、 金属手握棒、 或手握检测探棒。
根据本发明之方法, 其中该高中低周波注入讯号的主波之频率在 5MHz以 下。
根据本发明之方法,其中该人体皮肤之另一部位为人体之皮肤、穴道或经络, 其为量测相关器官健康状况之相关的量测部位 (量度点)。
因检测不同的器官退化 (疾病)或不同的传染性疾病, 各有其较佳相应的注入 讯号, 根据本发明之方法, 其中该高中低周波注入讯号的主波之频率、 波形、功 率与暂停时间, 及其载波之频率与波形, 可予以程序化调整设定, 以应不同的器 官退化 (疾病) 或不同的传染性疾病, 有较佳地相应量度的注入讯号, 使其量度 讯号得到较佳之讯号 /噪声比 (S/N值), 俾获得精确之电频谱值, 如此检测得的该 电频谱值, 更能精确的提供该受测者相关器官退化 (疾病) 或感染传染性疾病的 健康状况判读。 如于检测肝脏器官退化 (疾病) , 该较佳相应量度的注入讯号, 设定该主波之频率为 10.0 Hz之方波, 暂停时间为 0秒, 载波之频率为 200 Hz 的正弦波, 功率大小为主波振幅 1.0V。
根据本发明之方法,其中该身体之另一部位于检测肝脏器官, 其量度点为左 脚和右脚之大拇指内侧部位。
根据本发明之方法, 其中该相关器官之健康状况包含发炎状况、 正常状况、 退化状况及严重退化状况。
依据本发明之藉用该对人体皮肤注入高中低周波之一讯号以量度皮肤对该 讯号的阻抗之系统与方法, 用来检测身体健康状况的方法, 其中, 该电频谱值是 不经由人体皮肤对该注入讯号的阻抗值 (即不经人体皮肤而直接将输出的该注 入讯号与输入的该第一量度讯号予以短路,如图 2可程序分配输出器 204中开关 S可程序化地直接短路闭合)除以经由人体皮肤对该注入讯号的阻抗值之百分比 值。 该相关器官的相关量测部位 (简称量度点)结合其电频谱值, 根据本发明系统 对大量相关器官退化 (疾病 X不健康的状况)的研究与统计结果可据以判断人体相 关器官之健康状况系处于发炎, 正常, 退化及严重退化之状况。 根据一实施例, 一相关器官如肝脏器官, 其健康状况与电频谱值范围如下表一所示:
表一
Figure imgf000010_0001
又, 该表一在量测不同相关器官之健康状况时, 其电频谱值范围亦可为于不 同范围。
又,在量度相同器官之相同量度点时, 其电频谱值亦可因设定不同的百分比 值 (不同的放大倍率即有不同的电频谱值, 如为三百分比值之下的电频谱值即为 百分比值之三倍电频谱值)为不同数值。 本发明内的电频谱值系指百分比值。 根据本发明提供一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统, 以由一使用者用于治疗疾病或疼痛用之系统。
附图说明
图 1是本发明的一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统的示意图。
图 2是本发明的一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统的电路方块图。
图 3是本发明的该注入讯号 (一量测之注入讯号或一治疗的电波的频率、 波形、 暂停时间、 功率及其载波)的示意图。
图 4是本发明的该注入讯号该主波上的载波的示意图。
其中, 主要元件符号说明如下
对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的阻抗之系统 100, 200 外部个人计算机 102
USB界面 1021
具有高中低周波之能量输出装置 2001
皮肤对注入讯号的阻抗之量度装置 2002 微处理器 201
按键组合 2011
LED数字显示器 2012
可程序逻辑间 2013
存储器 2014
第一数位资料 2015
可程序主波与载波频率波形产生器 202 数位类比讯号转换器 2021
第一类比讯号 20211
第一低通滤波器装置 2022
第一波形讯号 2023
第一可程序类比开关 2024
第一开关讯号 20241
第二开关讯号 20242
第三开关讯号 20243
第二可程序类比开关 2025
第一低频滤波器 20221
第一滤波讯号 202211
第一中频滤波器 20222
第二滤波讯号 202221
第一高频滤波器 20223
第三滤波讯号 202231
可程序功率放大器 203
第二波形讯号 2031
可程序分配输出器 204
注入讯号 2041
输出过电流安全开关 2042
可程序分配输入器 205
第一量度讯号 2051
输入过电流安全开关 2052 固定讯号放大器 20521 可程序量度讯号放大器 206 第二量度讯号 2061
第二低通滤波器装置 207 第三量度讯号 2071
第二低频滤波器 20721 第一频带讯号 207211 第二中频滤波器 20722 第二频带讯号 207221 第二高频滤波器 20723 第三频带讯号 207231 第三可程序类比开关 2073 第一可程序量度讯号 20731 第二可程序量度讯号 20732 第三可程序量度讯号 20733 第四可程序类比开关 2074 过电流检知器 208
类比数位转换器 209
第二数位资料 2091
第一接触导电构件 2003 导电贴片 A1,A2,A3,A4
金属手握棒 B1,B2
金属脚踏钣 C1,C2
检测盘 D1
手握检测棒 F1
第二接触导电构件 2004 导电贴片 Α ,Α2, ,Α3 ' , Α4, 金属手握棒 Β ,Β2' 金属脚踏钣 CI ' ,C2' 手握检测探棒 El 受测者 3
回路讯号 31
开关 S
过电流检知讯号 A 2081
具体实施方式
本发明所谓人体健康与不健康的定义在中西医理论中都是" 以常测变" , 即一受测者人体生理值数据若落在人体常规值之范围内 (常态), 则人体处于健康 状况; 相反, 若人体生理数据若落在常规值之范围外 (非常态), 则人体处于不健 康状况 (病变), 例如, 西医的血液常规检查, GOT, GPT是检查肝脏疾病的主要 判别项目,其中, GOT常规值在 37 K单位 /ml以下与 GPT常规值在 42 K单位 /ml 以下, 二者若不在此常规值范围内, 则据此 (以常测变)判别该受测者肝脏处在不 健康状况 (不正常状况), 则须加以追踪该受测者的身体肝脏健康状况; 又如中医 用来诊断疾病的把脉, 正常 (健康)的脉象称之为平脉, 其它如浮脉, 沈脉, 数脉, 迟脉等皆属不正常之脉象, 据此 (以常测变)判别为身体的各种不健康状况。 在本 发明一较佳具体实例中,利用对人体皮肤注入高中低周波之一讯号以量度皮肤对 该讯号的阻抗之系统与方法, 如上表一所示, 电频谱值若落在人体常规值之范围 内, 则处于正常状况 (健康状况); 相反, 若电频谱值落在常规值之范围外, 则处 于非正常状况 (不健康状况)。
请参阅图 1及图 2, 图 1是本发明的一种对人体皮肤注入高中低周波之一讯 号以量度皮肤对该讯号的阻抗之系统的示意图,图 2是本发明的一种对人体皮肤 注入高中低周波之一讯号以量度皮肤对该讯号的阻抗之系统 200(同图 1之 100) 的电路方块图,该对人体皮肤注入高中低周波一讯号以量度皮肤对该讯号的阻抗 之系统 100具有一本体 101。 该本体 101向外电连接可程序化地选择一第一接触 导电构件 2003的一导电贴片 A1,A2,A3,A4、一金属手握棒 B1,B2、一金属脚踏 钣 C1,C2、一检测盘 Dl、和手握检测棒 F1其中的一个, 与一第二接触导电构件 2004的一导电贴片 ΑΓ ,A2, ,A3, ,A4'、 一金属手握棒 ΒΓ ,Β2'、 一金属脚 踏钣 CI ' ,C2'、 和手握检测探棒 El其中的一个。 当一受测者使用本发明量度 系统作肝脏器官健康状况的检测时,如图 2,本系统提供一高中低周波之一讯号, 该受测者 3—手握着该第一接触导电构件 2003的该手握检测棒 Fl, 由此该高中 低周波之讯号转为一注入讯号,注入于该受测者 3身体的一部份, 另由一检测人 手握该第二接触导电构件 2004的该检测探棒 E1接触该受测者之相关器官的相关 量测部位 (量度点) (如检测肝脏器官量度点为人体左脚和右脚的大拇指内侧部 位), 以形成一个电路回路, 可于一 LED显示器 2012显示出该电频谱值, 该电 频谱值是不经由人体皮肤 (该注入讯号在无负载状态, 即不经人体皮肤而直接将 第二波形讯号 2031经由可程序分配输出器 204的开关 S可程序化地直接闭合与 该可程序分配输入器 205后端的该第一量度讯号 2051予以直接短路)对该注入讯 号的阻抗值除以经由人体皮肤 (该注入讯号在有负载状态如图 2依循检测的电路 路径)对该注入讯号的阻抗值的百分比值。 该具有高中低周波之能量输出装置另 包括一 USB界面 1021, 电连接至该微处理器 201, 提供用于连接至一外部个人 计算机 102(例如, 可为个人计算机, 笔记型计算机等), 以于该计算机之显示器 上显示一量测结果与用予相关量测资料之储存与运用。
请参阅图 2, 图 2是本发明的一种对人体皮肤注入高中低周波之一讯号以量 度皮肤对该讯号的阻抗之系统 200(同图 1之 100)的电路方块图, 具有一高中低 周波之能量输出装置 2001及一皮肤对注入讯号的阻抗之量度装置 2002, 该高中 低周波之能量输出装置 2001包含有一微处理器 201。 该系统 200并包含: 一按 键组合 2011电连接至该微处理器 201, 用于产生一输入设定相关高中低周波该 主波之频率、 波形、 功率与暂停时间, 及其载波之频率与波形之相关数据, 其所 输入的波形可为正弦波, 方波, 三角波, 梯形波, 或其他各种形状的波形; 于输 入其他各种不规则形状的波形时则只须将不规则波形的相关波形数据输入即可; 一 LED数字显示器 2012, 电连接至该微处理器 201, 用于显示该量度系统相关 量测数值 (电频谱值)与由该按键组合 2011输入的相关资料等; 一可程序逻辑闸 2013电连接至该微处理器 201,用以程序规划硬件逻辑以控制该装置系统硬件的 逻辑组合; 一存储器 2014电连接至该微处理器 201, 用于储存记忆该微处理器 所处理之数据资料与程序资料。
该具有高中低周波之能量输出装置 2001包含有一可程序主波与载波频率波 形产生器 202, 用于根据该微处理器输出之该主波之频率、 波形、 与暂停时间, 及其载波之频率与波形相关的一第一数位资料 2015产生一第一波形讯号 2023, 其中包含有一组数位类比转换器 2021及一第一低通滤波器装置 2022, 该组数位 类比转换器 2021用于将该第一数位资料 2015转换成一第一类比讯号,再将该第 一类比讯号通过该第一低通滤波器装置 2022, 以滤除数位类比转换器 2021的谐 振噪声而输出一高中低周波的该第一波形讯号 2023。其中,低周波频率是 1 KHz 以下, 中周波频率是 1 KHz〜100 KHz, 高周波是 100 KHz〜5 MHz。
根据本发明, 该可程序主波与载波频率波形产生器 202包括有:
一组数位类比讯号转换器 2021, 电连接至该微处理器 201, 用于产生一第一 类比讯号 20211 ;
一第一可程序类比开关 2024, 电连接至该组数位类比讯号转换器 2021, 用 于输入该第一类比讯号 20211后可程序化选择输出一第 n开关讯号 20241, 20242, 20243(n为大于 0之整数);
一第一低通滤波器装置 2022, 该第一可程序类比开关 2024电连接至一第 1 至第 n滤波器 20221, 20222, 20223 , 该第 n滤波器 20221,20222, 20223用于输入 对应的该第 n开关讯号 20241, 20242, 20243 以产生一第 n滤波讯号 202211, 202221, 202231; 及
一第二可程序类比开关 2025, 电连接至该第一低通滤波器装置 2022且由该 微处理 201器所控制, 用于输入对应的该第 n滤波讯号 202211, 202221, 202231 以输出该第一波形讯号 2023。在本发明一较佳具体实例中,该第 n滤波器 20221, 20222, 20223分别为一第一低频滤波器 20221, 一第一中频滤波器 20222及一第 一高频滤波器 20223。
该第一波形讯号 2023输入至一可程序功率放大器 203, 以将该第一波形讯 号 2023的功率在系统的电源电压下安全范围内可程序化地设定放大 (亦可衰减) 而产生一第二波形讯号 2031, 该可程序功率放大器 203系电连接至该可程序主 波与载波频率波形产生器 202。
该第二波形讯号 2031输入至一可程序分配输出器 204, 经由可程序化的选 择该可程序分配输出器 204输出端与选择的一该第一接触导电构件 2003相电连 接,用以转换该第二波形讯号 2031成一注入讯号 2041(作为该受测者检查身体健 康状况之该注入讯号或该使用者治疗疾病或疼痛用的治疗电波), 例如: 一受测 者 3将该导电贴片 A1压贴在受测者 3手的一部位,该受测者 3本人 (或另一检测 者)的另一只手则手握住该手握探棒 El, 以接触该受测者 3的相关器官的相关的 量测部位 (量度点), 如此产生一回路讯号 31流经该受测者 3身体, 本装置输出 的该注入讯号即行串接注入该受测者 3身体。
之后,该回路讯号 31经由选择的 1个该第二接触导电构件 2004输入至该系 统 200之该皮肤对注入讯号的阻抗之量度装置 2002之一可程序分配输入器 205, 自其输出一第一量度讯号 2051。
接着, 该第一量度讯号 2051输入至一固定讯号放大器 20521, 该固定讯号 放大器 20521连接至该可程序分配输入器 205, 用以放大该第一量度讯号 2051 , 一过电流检知器 208连接至该固定讯号放大器 20521, 当该第一量度讯号 2051 经由该固定讯号放大器 20511放大后, 输出至该过电流检知器 208, 用以比较检 测第一量度讯号,若该第一量度讯号的电流超过一可程序化设定的预定值或人体 最大安全电流值时, 则输出一过电流检知讯号 A 2081 , 至该可程序分配输出器 204内的该输出过电流安全开关 2042和该可程序分配输入器 205内的该输入过 电流安全开关 2052, 而将絃可程序分配输出器 204与该可程序分配输入器 205 关闭,如此令该第二波形讯号不再注入该受测者,以防该受测者过大电流的伤害, 该过电流检知讯号 2081也同时输入该微处理器 201, 经由该微处理器 201送出 过电流检知讯息在该 LED数字显示器 2012显示过电流状况。以防止过大的电流 流经该受测者 3, 以保障受测者的使用安全, 因为人体所能容忍的电流有一安全 最大值;若该第一量度讯号的电流没有超过该可程序化设定的预定值或人体最大 安全电流值时, 则不切断该可程序分配输出器 204内的该输出过电流安全开关 2042或 /与该可程序分配输入器 205内的该输入过电流安全开关 2052, 量测检查 继续进行。
该第一量度讯号 2051输入至一可程序量度讯号放大器 206, 将该第一量度 讯号 2051放大后输出一第二量度讯号 2061, 第二量度讯号 2061输入一第三可 程序类比开关 2073后经过一第二低通滤波器装置 207过滤噪声后, 再输入一第 四可程序类比开关 2074后, 产生一第三量度讯号 2071, 再输入至一类比数位转 换器 209, 后输出一第二数位资料 2091(为该受测者皮肤对该注入讯号的数字化 的阻抗值)至该微处理器 201,该微处理器 201资料运算处理系以无负载的第二数 位资料 (即该第二波形讯号 2031经由将可程序分配输出器 204之选择开关 S可程 序化地直接予以短路闭合再电连至该可程序分配输入器 205之输出端成为该第 一量度讯号 2051, 再经由讯号处理及类比数位讯号转换器 209之转换所产生的 第二数位资料 2091, 亦即不经该受测者人体的电路回路所产生的第二数位资料) 除以有负载的该第二数位资料 (该注入讯号经该受测者人体的电路回路所产生的 第二数位资料)的百分比值 (电频谱值), 再输出至 LED数字显示器 2012, 用以显 示高中低周波之一讯号注入于该受测者后身体皮肤对该讯号阻抗变化值 (为 -百 分比值, 亦称电频谱值)。
根据本发明, 该第二低通滤波器装置 207包括:
一第三可程序类比开关 2073, 连接至该可程序量度讯号放大器 206, 用于输 入该第二量度讯号 2061而产生一第 1至一第 n可程序量度讯号 20731, 20732, 20733;
n个第二低通滤波器 20721, 20722, 20723 , 连接至该第三可程序类比开关 2073 , 用于接收该第 n可程序量度讯号 20731, 20732, 20733而产生一第 n频带 讯号 207211, 207221, 207231 ; 及
一第四可程序类比开关 2074, 连接至该 n个滤波器 20721, 20722, 20723, 用 于接收该第 n频带讯号 207211, 207221, 207231, 输出该第三量度讯号 2071。 在 本发明一较佳具体实例中, 第 n个第二低通滤波器 20721, 20722, 20723分别为 一第二低频滤波器 20721、 一第二中频滤波器 20722、 一第二高频滤波器 20723, 且其相对应频带之运作系与该第一低通滤波器装置 2022之该第一低频滤波器 20221、 第一中频滤波器 20222及第一高频滤波器 20223在程序选择运作上系相 对应的频带关系。
请参阅图 3, 图 3是本发明的该注入讯号 2041
(作为该受测者检查身体健康状况之该注入讯号或该使用者治疗疾病或疼痛用的 治疗电波)的示意图, 其中两相邻波形之间为暂停时间 t2, 而波形所占有的时间 是 tl, 其中, 横轴是时间, 纵轴是振幅 (电压值)。
请参阅图 4, 图 4是本发明的注入讯号 2041 (作为该受测者检查身体健康状 况之该注入讯号或该使用者治疗疾病或疼痛用的治疗电波)之主波及其载波的波 形之一示意图, 载波频率与波形可程序化地设定 (一般载波频率不小于主波频率 10倍), 其中两相邻主波的波形之间为暂停时间 t4, 而主波波形所占有的时间是 t3, 其中, 横轴是时间, 纵轴是振幅 (电压值)。
本发明的优点如下:
(1)就本发明其中一具有高中低周波之能量输出装置部份- --传统的一般高中 低周波治疗仪无载波可程序化地设定其频率及波形的功能,主波也无可程序化地 设定其频率、波形、功率和暂停时间的功能, 但对各种不同的疾病或疼痛在不同 的疗程阶段须有各种不同的治疗电波的设定条件,因此传统的一般高中低周波治 疗仪会显著地影响其治疗的效果,针对上述现有技术之缺失, 本发明提供一具有 高中低周波之能量输出装置,该装置输出的主波之频率、波形、功率与暂停时间, 及其载波之频率与波形在安全规定值之内能可程序化地设定后输出一注入讯号 (作为该受测者检查身体健康状况之该注入讯号或该使用者治疗疾病或疼痛用的 治疗电波),即可解决上述传统高中低周波治疗仪之缺失,显著地增加治疗效果。。
(2)就本发明的皮肤对注入讯号的阻抗之量度装置部份- -本发明一种对人体 皮肤注入高中低周波能量用以治疗的电波可经由本发明之量度装置,撷取量度讯 号, 数字化, 储存, 处理, 输出电频谱值至显示器, 让一使用者可据以对所加注 高中低周波注入讯号的频率、 波形、 功率、 暂停时间, 及其载波的频率、 波形因 有电频谱值之读值, 据以作较佳输出设定值之参考依据 (较佳的治疗效果是指该 使用者经高中低周波治疗时或治疗后, 该电频谱值趋向更接近落在常规值范围 内), 如此因有电频谱值的量度装置的设计, 使得高中低周波治疗达较好的效果。
(3)人体皮肤对加注直流电阻抗变化的量度检测是目前公认可得知身体健康 状况检测的一种方法, 行之有年, 如日本良导络系统、 西德 Dr. VoLL系统等。 但对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的阻抗之系统与方 法, 作为身体健康状况的检测方法与应用目前尚未有之。
人体皮肤对加注直流电阻变化的量度用于检测身体健康状况,如日本良导络 系统等仅能提供受测者在最近某一段时间 (多长时间不可确定)的非实时性的身 体健康状况讯息,无法实时性地提供受测者的相关传染性疾病、相关的器官退化 (疾病)和相关的肿瘤的讯息。
针对上述现有技术之缺失,本发明提供一量度系统与方法, 用以量度人体皮 肤 (如人体的经络、 穴位等)对注入各种频率及波形的讯号阻抗变化, 用来检测身 体健康状况, 可实时性地提供受测者的相关传染性疾病、 相关器官退化 (疾病)和 相关肿瘤的讯息, 作为检测身体健康状况的量度系统与方法, 为极大进步性。例 如: 检查一受测者现在 (实时性的)是否感染一传染性的肠胃型感冒, 可藉助本发 明系统 (1)设定该注入讯号为主波之频率为 8.5 Hz的正方波, 暂停时间为 0秒, 载波的频率为 170 Hz的正弦波, 功率大小为主波振幅 1.0V, (2)相关量度点为左 手和右手之食指部位, 其电频谱值倶为 60以上 (发炎状况), 经由大量的相关疾 病的研究与统计, 即可作为判读该受测者现在 (实时性的)是否感染该传染性的肠 胃型感冒。 (4)目前医学界, 尚未发现一种仪器装置能让医师对病人的用药、 开刀、 化 疗、 放疗等治疗后, 有一种简单、 快速、 非侵入性的量度系统与方法, 能提供医 师作为对病人治疗后,对其效果与整体影响的实时性讯息, 针对上述现有技术之 缺失, 本发明提供一量度系统与方法, 如本发明的优点 (3)所述本发明的一量度 系统与方法, 可用来检测身体健康状况, 可实时性地提供受测者的相关传染性疾 病、 相关器官退化 (疾病)和相关肿瘤的讯息, 即可据以提供医师简单、 快速、 非 侵入性的量度系统与方法, 对病人治疗后, 对其效果与整体影响的实时性讯息, 例如一医师对一病人用药等治疗后,藉由本量度系统, 量度该病人相关器官的量 度点的电频谱值, 由该电频谱值是否更趋向常规值范围内变化, 据此医师可以简 单、 快速、 非侵入性地得到该病人治疗后, 对其效果与整体影响的实时性讯息, 并作为下次治疗用药参考。
(5)就本发明的另一目的为一种对人体皮肤注入高中低周波之一讯号以量度 该讯号的阻抗之系统作为检查该受测者身体健康状况。然人体皮肤对各种不同的 器官退化 (疾病)和不同的传染性疾病各有其较佳地相应量度的注入讯号。 本发明 的一种输出高中低周波该注入讯号其主波之频率、波形、 功率与暂停时间, 及其 载波之频率与波形在安全规定值内能提供使用者 (个人、 病人、 医生、 研究者等) 能可程序化地调整设定, 使其量度讯号得到最好的讯号 /噪声比, 如此检测得的 该电频谱值, 更能精确的提供该受测者相关器官退化 (疾病)和相关传染性疾病的 健康状况判读。
(6)检测盘: 该具有高中低周波之能量输出装置另包括一检测盘 Dl, 系一导 电金属片或一导电容器 (与外界作电绝缘隔离), 电连接至可程序分配输出器 204, 其目的是可将检测盘 D1上所放置的物质 (如药物等)之讯息 (物质之讯息其等效电 路可影响回路之阻抗值), 可程序化地设定是否将该检测盘并接于第二波形讯号 2031 , 检测盘 D1放置的物质 (如药物等)的讯息是否影响该受测者的电频谱值, 即可经由本量度系统得知, 据以提供该受测者对相关物质 (检测盘所放置的物质) 是正面或负面的影响评估。
(7)安全性: 就本发明一种对人体皮肤注入高中低周波之一讯号以量度皮肤 对该讯号的阻抗之系统安全性之部份--由物理定律得知电流 1=电压 V/阻抗 Z。虽 然高中低周波注入于人体的电压值都很低,故平常注入而流经于人体之电流都很 小, 但是当人体与某一频率波形成共振态时, 其人体皮肤阻抗 Z会变得很低,以 至于造成极大电流注入于人体而造成伤害。本发明由该输出过电流安全开关 2042 和该输入过电流安全开关 2052(示于图 2)的设置,加注人体的第一量度讯号 2051 经固定讯号放大器 20521放大再输入过电流检知器 208与可程序化设定的预定值 或人体最大安全电流作比较, 若电流值过大, 则输出一过电流检知讯号 2081至 该可程序分配输出器 204的该输出过电流安全开关 2042, 与该可程序分配输入 器 205的该输入过电流安全开关,而将该可程序分配输出器与该可程序分配输入 器同时关闭 2052, 如此令该第二波形讯号不再注入该受测者 3, 以防该受测者过 大电流的伤害, 该过电流检知讯号也同时输入该微处理器 201, 经由该微处理器 201送出过电流检知讯息在该 LED数字显示器 2012, 显示过电流状况。
实施例
依据本发明之一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统与方法,其中, 该对人体皮肤注入高中低周波之一讯号以量度皮 肤对该讯号的阻抗之系统是用于评估一受测者之身体健康状况, 一具体实施例, 例如, 检查一受测者肝脏器官的健康状况:
- 经由本发明之一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该 讯号的阻抗之系统与方法, 对大量的相关器官退化 (疾病)研究与统计结果, 知道 肝脏器官的病变不健康 (不正常状况)可藉由本发明系统之 (1)将注入人体的该注 入讯号设定为主波之频率为 10.0 Hz之正方波, 暂停时间为 0秒, 载波之频率为 200 Hz的正弦波, 功率大小为主波振辐 1.0 V; (2)肝脏器官的量度点为左脚和右 脚的大拇指,相关量度点的电频谱值,其中有任一电频谱值落在严重退化状况 (不 正常状况) (电频谱值 0〜20,如表一所示),作为肝脏器官的病变不健康 (不正常状 况)的评估。
-- -一受测者作肝脏器官健康状况的检查, 藉助本发明系统将其注入人体的 该注入讯号设定为主波之频率为 10 Hz之正方波, 暂停时间为 0秒, 其载波之频 率为 200 Hz的正弦波, 功率大小为主波振辐 1.0 V, 由该受测者左手或右手握一 手握检测棒 Fl, 检测者手 (左手或右手均可)握一手握检测探棒 El, 以量度该受 测者左脚和右脚的大拇指内侧部位 (为肝脏器官的量度点), 得右脚量度点的电频 谱值 48(正常状况), 左脚的量度点的电频谱值 16(严重退化状况), 藉由本发明之 系统, 对大量的相关肝脏器官退化 (疾病)的研究与统计结果, 可据以检测该受测 者肝脏器官是处在不健康状况 (不正常状况)。 - -从西医的健检中,亦发现该受测者有某一程度肝脏器官的纤维硬化疾病 <

Claims

权 利 要 求 书
1.一种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的阻抗之系统, 其包括:
一具有高中低周波之能量输出装置,用于可程序化地产生高中低周波能量之 一注入讯号, 以施加该注入讯号于一受测者身体的一部份; 及
一皮肤对注入讯号的阻抗之量度装置, 连接至该受测者身体的另一部份 (量度 点), 与该受测者身体的该注入讯号形成一电路回路, 并经由该电路回路输出一 量度讯号, 用于量测出该受测者之皮肤对于该注入讯号的阻抗变化值 (电频谱 值), 依据该电频谱值是否落于常规值范围内, 用来检测出该受测者之身体健康 状况或作为该注入讯号的较佳设定值参考,
其中该具有高中低周波之能量输出装置包括:
一输入装置, 用以产生可程序化地设定之具高中低周波的一主波之频 率、 波形、 功率与暂停时间, 及其载波之频率与波形之输入资料;
一可程序逻辑间, 用以程序规划硬件逻辑间以控制该系统的逻辑组合; 一微处理器,连接至该输入装置及该可程序逻辑间, 经由一运用程序与 该微处理器的结合,用于运算处理该输入资料并输出对应的可程序化的该主波频 率、 波形、 暂停时间, 及其载波频率、 波形之一第一数位资料;
一可程序主波与载波频率波形产生器,连接至该微处理器, 具有一组数 位类比转换器, 两个可程序类比开关, 分别连接至一第一低通滤波器之输入端与 输出端, 及该第一低通滤波器装置, 具有 n个第一滤波器 (n为大于 0之整数,以 下同)该组数位类比转换器用以将该第一数位资料转换成具有该主波之频率、 波 形、与暂停时间, 及其载波之频率与波形的一第一类比讯号, 而该第一低通滤波 器装置用以滤除该第一类比讯号之数位类比转换器的谐振噪声,并藉由该两个可 程序类比开关之选择而产生一可程序化的该主波之频率、 波形、 与暂停时间,及 其载波之频率与波形而输出一第一波形讯号;
一可程序功率放大器, 连接至该可程序主波与载波频率波形产生器,用 于将该第一波形讯号的功率可程序放大而产生一具适当功率的一第二波形讯号; 及
一可程序分配输出器,连接至该可程序功率放大器, 输入该第二波形讯 号,并通过可程序化地选择之一第一接触导电构件而转换成该注入讯号注入至该 受测者身体的一部份;
且其中该皮肤对注入讯号的阻抗之量度装置包括:
一可程序分配输入器,与可程序化地选择之一第二接触导电构件而串接 于该受测者身体之另一部份 (量度点), 与该注入讯号形成一电路回路, 并经由该 电路回路输出一第一量度讯号;
一可程序量度讯号放大器, 输入该可程序分配输入器之该第一量度讯 号, 用于将该第一量度讯号放大后输出一第二量度讯号;
一第二低通滤波器装置,连接至该可程序量度讯号放大器, 其具有两个 可程序类比开关与 n个第二滤波器 (n为大于 0之整数),该两个可程序类比开关, 用以可程序选择所需要之频带,该 n个第二滤波器用于过滤该第二量度讯号之噪 声, 以产生一第三量度讯号;
一类比数位转换器,连接至该第二低通滤波器装置, 用于将该第三量度 讯号由类比讯号转换成一第二数位资料而输出至该微处理器,以利用该微处理器 进行该第二数位资料之处理; 及
一输出装置,用以显示该微处理器所处理结果之一输出讯号, 其代表该 受测者对该注入讯号加注该身体后, 身体对该注入讯号的阻抗变化值 (简称电频 谱值), 用来检测该受测者的身体健康状况, 该输出装置亦用以显示由该输入装 置所输入的相关资料。
2.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统,其中该对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之电频谱值为一百分比值,该百分比值系以不经由该人体皮肤对该注入讯 号的阻抗值除以经由该人体皮肤对该注入讯号的阻抗值之百分比值。
3.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统,其中该第一低通滤波器装置之 n个第一滤波器具有并联之一第一 低频滤波器、一第一中频滤波器及一第一高频滤波器, 且该第二低通滤波器装置 之 n个第二滤波器具有并联之一第二低频滤波器、一第二中频滤波器及一第二高 频滤波器, 且其中该第一低通滤波器装置之该第一低频滤波器、该第一中频滤波 器及该第一高频滤波器与该第二低通滤波器装置之该第二低频滤波器、该第二中 频滤波器及该第二高频滤波器在运作上系相对应且由可程序化地选定。
4.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统,其另包括一固定讯号放大器及一过电流检知器, 该固定讯号放大 器连接至该可程序分配输入器,用以放大该第一量度讯号, 该过电流检知器连接 至该固定讯号放大器,当该放大之该第一量度讯号的电流超过一可程序化设定的 预定值或人体安全规定最大电流值时,则输出一过电流检知讯号至该可程序分配 输出器的该输出过电流安全开关,与该可程序分配输入器的该输入过电流安全开 关, 而将该可程序分配输出器与该可程序分配输入器同时关闭, 如此令该第二波 形讯号不再注入该受测者, 以防该受测者过大电流的伤害, 该过电流检知讯号也 同时输入该微处理器, 经由该微处理器送出过电流检知讯号在该 LED数字显示 器, 显示过电流状况。
5.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统, 其中该高中低周波注入讯号之主波之频率系在 5 MHz以下可程 序化地设定。
6.如权利要求 5所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统, 其中该主波之频率在 100 KHz以下, 其载波之频率与波形可由 程序化设定。
7.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统, 其中该受测者身体的一部份是一人体之皮肤、 穴道或经络。
8.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统, 其另包含一存储器, 连接至该微处理器, 用以记忆该微处理器所 处理之数据资料或该系统本身程序的资料。
9.如权利要求 8所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号 的阻抗之系统, 其中该存储器是一快闪存储器 (flash memory, FROM)或静态存储 器 (SRAM)。
10.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统, 其中该输入装置为一按键组合。
11.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统, 其中该输出装置为一 LED数字显示器。
12.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统, 其中该第一接触导电构件为一导电贴片、 金属脚踏钣、金属手 握棒或手握检测棒。
13.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统,其中该第一接触导电构件另包括一检测盘, 电连接至该可程序 分配输出器, 用以电连传送一其上所承载之物质讯息至该可程序分配输出器。
14.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统, 其中该第二接触导电构件为一导电贴片、 金属脚踏钣、金属手 握棒或手握检测探棒。
15.如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯 号的阻抗之系统,其中该第一波形讯号之该主波的波形, 为可程序化地设定之一 正弦波、 方波、 三角波或其他波形, 该载波亦为可程序化设定的波形。
16. 一种皮肤对高中低周波的一注入讯号的阻抗之量度装置, 其包括:
一可程序分配输出器, 用于经由一第一接触导电构件输出高中低周波的 一注入讯号至一受测者身体的一部份;一可程序分配输入器, 与可程序化地选择 的一第二接触导电构件而串接于该受测者身体之另一部份,与该注入讯号形成一 电路回路, 并经由该电路回路输出一第一量度讯号;
一可程序量度讯号放大器, 接收该可程序分配输入器之该第一量度讯号,用 于将该第一量度讯号放大后输出一第二量度讯号;
一第二低通滤波器装置,连接至该可程序量度讯号放大器, 其具有两个可程 序类比开关与 n个第二滤波器 (n为大于 0之整数), 该两个可程序类比开关, 用 以可程序选择所需要之频带, 该 n个第二滤波器用于过滤该第二量度讯号之噪 声, 以产生一第三量度讯号;
一类比数位转换器,连接至该第二低通滤波器装置, 用于将该第三量度讯号 由类比讯号转换成一数位资料而输入至一微处理器,以利用该微处理器进行该数 位资料之处理; 及
一输出装置, 用以显示该微处理器所处理结果之一输出讯号, 其代表该受测 者身体对该高中低周波的注入讯号加注该身体后,身体对该注入讯号的阻抗变化 值 (电频谱值), 用来检测该受测者的身体健康状况。
17.如权利要求 16所述的皮肤对高中低周波的一注入讯号的阻抗之量度装置, 其 中该电频谱值为一百分比值。
18.如权利要求 16所述的皮肤对高中低周波的一注入讯号的阻抗之量度装置, 其 中, 该第二低通滤波器装置包括: 一第三可程序类比开关, 连接至该可程序量度讯号放大器, 用于接收该第二 量度讯号而产生一第 n可程序讯号;
n个第二滤波器, 其滤波器频带可程序化地相应于该可程序分配输出器之高 中低周波的注入讯号之输出频率,连接至该第三可程序类比开关, 用于接收该第 n可程序讯号而产生所需频带之第 n频带讯号, 其中为该 n个第二滤波器包含一 第二低频滤波器、 一第二中频滤波器、 以及一第二高频滤波器; 及
一第四可程序类比开关,连接至该 n个第二滤波器, 用于可程序选择接收该 第 n频带讯号输出, 以产生该第三量度讯号。
19.如权利要求 16所述的皮肤对高中低周波的一注入讯号的阻抗之量度装置, 其 中该高中低周波的注入讯号的主波之频率系在 5 MHz以下。
20.—种对人体皮肤注入高中低周波之一讯号以量度皮肤对该讯号的阻抗之方 法, 包括下列步骤:
提供一高中低周波之该讯号将该高中低周波之该讯号经由可程序化选择一 第一接触导电构件的手握检测棒,注入于一受测者的人体皮肤之一部位而成一注 入讯号, 其中该注入讯号之主波之频率、 波形、 功率与暂停时间, 及其载波之频 率与波形在安全规定内可程序化地设定;
于该第一接触导电构件、该受测者皮肤之一部位及与该受测者皮肤之另一部 位 (量度点)串接至可程序化地选择之一第二接触导电构件的手握检测探棒形成 一电路回路, 并经由该电路回路输出一量度讯号, 其中该受测者皮肤之另一部位 系受测者相关器官的一相关的量测部位 (量度点);
经由对该量度讯号之撷取、放大与滤除噪声、类比数位转换以及一微处理器 之资料处理, 以产生该受测者相关量度点之一电频谱值; 及
经由结合该相关器官的量度点和该电频谱值与一常规值之比对以检查该受 测者相关器官之健康状况。
21.如权利要求 20所述的方法, 其中该对人体皮肤注入高中低周波之一讯号以量 度皮肤对该讯号的电频谱值为一百分比值,该百分比值系以不经由该人体皮肤对 该注入讯号的阻抗值除以经由该人体皮肤对该注入讯号的阻抗值之百分比值。
22.如权利要求 20所述的方法, 其中该第一接触导电构件为一导电贴片、 金属脚 踏钣、 金属手握棒、 或手握检测棒, 该第二接触导电构件为一导电贴片、 金属脚 踏钣、 金属手握棒、 或手握检测探棒。
23.如权利要求 20所述的方法, 其中该高中低周波注入讯号的主波之频率在 5MHz以下。
24.如权利要求 20所述的方法, 其中该人体皮肤之另一部位为人体之皮肤、 穴道 或经络, 其为量测相关器官健康状况之相关的量测部位 (量度点)。
25.如权利要求 20所述的方法,其中该高中低周波注入讯号的主波之频率、波形、 功率与暂停时间,及其载波之频率与波型可予以程序化调整设定, 用以得到较佳 之讯号 /噪声比 (S/N值), 俾获得正确之电频谱值。
26.如权利要求 24所述的方法, 其中该身体之另一部位于检测肝脏器官, 其量度 点为左脚和右脚之大拇指内侧部位。
27.如权利要求 20所述的方法, 其中该相关器官之健康状况包含发炎状况、 正常 状况、 退化状况及严重退化状况。
28.—种如权利要求 1所述的对人体皮肤注入高中低周波之一讯号以量度皮肤对 该讯号的阻抗之系统, 系用于治疗疾病或疼痛。
PCT/CN2013/076488 2013-05-30 2013-05-30 量度皮肤阻抗之系统与方法 WO2014190522A1 (zh)

Priority Applications (1)

Application Number Priority Date Filing Date Title
PCT/CN2013/076488 WO2014190522A1 (zh) 2013-05-30 2013-05-30 量度皮肤阻抗之系统与方法

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/CN2013/076488 WO2014190522A1 (zh) 2013-05-30 2013-05-30 量度皮肤阻抗之系统与方法

Publications (1)

Publication Number Publication Date
WO2014190522A1 true WO2014190522A1 (zh) 2014-12-04

Family

ID=51987879

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/CN2013/076488 WO2014190522A1 (zh) 2013-05-30 2013-05-30 量度皮肤阻抗之系统与方法

Country Status (1)

Country Link
WO (1) WO2014190522A1 (zh)

Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2000028892A1 (en) * 1998-11-13 2000-05-25 Micromedical Industries Limited Wrist mountable monitor
CN1387821A (zh) * 2001-05-29 2003-01-01 株式会社百利达 具有确定被测量对象的功能活体测量设备
CN1505489A (zh) * 2001-03-01 2004-06-16 �����������ֶ� 生物体反应波形信息的分析方法和装置以及诊断装置
CN2669791Y (zh) * 2003-08-05 2005-01-12 彭飞 人体阻抗测量装置
CN1592596A (zh) * 2000-12-28 2005-03-09 Z-技术加拿大公司 用于检测和诊断疾病的改进的电阻抗方法和设备
DE202012009097U1 (de) * 2012-07-26 2013-02-08 Hou-Chieh Lee Energieabgabevorrichtung mit Frequenzwellen

Patent Citations (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2000028892A1 (en) * 1998-11-13 2000-05-25 Micromedical Industries Limited Wrist mountable monitor
CN1592596A (zh) * 2000-12-28 2005-03-09 Z-技术加拿大公司 用于检测和诊断疾病的改进的电阻抗方法和设备
CN1505489A (zh) * 2001-03-01 2004-06-16 �����������ֶ� 生物体反应波形信息的分析方法和装置以及诊断装置
CN1387821A (zh) * 2001-05-29 2003-01-01 株式会社百利达 具有确定被测量对象的功能活体测量设备
CN2669791Y (zh) * 2003-08-05 2005-01-12 彭飞 人体阻抗测量装置
DE202012009097U1 (de) * 2012-07-26 2013-02-08 Hou-Chieh Lee Energieabgabevorrichtung mit Frequenzwellen

Similar Documents

Publication Publication Date Title
Sakai et al. Specific acupuncture sensation correlates with EEGs and autonomic changes in human subjects
Mabrouk et al. Robust longitudinal ankle edema assessment using wearable bioimpedance spectroscopy
Johng et al. Frequency dependence of impedances at the acupuncture point Quze (PC3)
US20090264776A1 (en) Measurement of physiological characteristics
US11020005B2 (en) Neuromechanical algometer
KR20060129507A (ko) 살아있는 유기체 내에서 비침습적으로 물질의 양적 정보를측정하기 위한 방법 및 장치
WO2017161451A1 (en) An apparatus and method to locate, measure, monitor, and treat inflammation of the skin&#39;s soft tissue and fascia layers
AU743327B2 (en) Device for local magnetotherapy
US20120271192A1 (en) Method and apparatus for analysing the structure of bone tissue
US20160270661A1 (en) System for evaluating pain modulation, spatial and/or temporal summation of pain or descending inhibition of pain in a human
US20060020223A1 (en) Systems and methods of utilizing electrical readings in the determination of treatment
Huang et al. Acupuncture effects on the pulse spectrum of radial pressure pulse in dyspepsia
GB2530355A (en) Electric impedance tomographic device
Yang et al. A design of bioimpedance spectrometer for early detection of pressure ulcer
TWI612984B (zh) 一種對人體皮膚注入高中低週波之一訊號以量度皮膚對該訊號的阻抗之系統
WO2014190522A1 (zh) 量度皮肤阻抗之系统与方法
CN110584665A (zh) 一种健康检测装置
TWM468292U (zh) 一種對人體皮膚注入高中低週波之一訊號以量度皮膚對該訊號的阻抗之系統及其裝置
WO2019168500A1 (en) Connection quality assessment for eeg electrode arrays
KR100745521B1 (ko) 수지요법 장치
TWI296103B (zh)
Szczuka et al. Electrodermal activity of the skin assessed using Ryodoraku method after a single training session in taekwondo competitors
TWM454180U (zh) 一種具有高中低週波之能量輸出裝置及結合一皮膚對電頻譜阻抗之量度裝置
TWI544903B (zh) The scintillating device and its scanning method
RU2192166C2 (ru) Способ диагностики функционального состояния организма по состоянию биологически активных точек

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 13885920

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 13885920

Country of ref document: EP

Kind code of ref document: A1