FR2831012A1 - Mobile phone power supply has automatic and manual switching of backup battery - Google Patents

Abstract

A mobile phone power supply (5a) has an automatic and manual switch from primary (5b) to backup (5c) battery power supply with automatically controlled external separate or simultaneous charging of either battery. Includes an INDEPENDENT claim for single button calling of an emergency number with switching to the backup supply.

Description

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POWER SUPPLY DEVICE AND MOBILE TELEPHONE
INCORPORATING
The invention relates to a power supply device for a wireless electronic device, as well as a mobile telephone incorporating such a device.

 Such a power supply device finds applications, for example, in cordless telephony devices such as mobile telephones, cordless telephone handsets of the DECT (Digital European Cordless Telephone) type or the like. However, it can also be used in personal digital assistants, and in general in all wireless electronic devices which include autonomous power supply means. Such means are today produced by a battery, that is to say a rechargeable active component which is the threshold for a reversible chemical reaction. In discharge, this chemical reaction makes it possible to generate an electrical current suitable for the electrical supply of the device, from the electrical energy stored without chemical form in the battery. When charging, this reaction makes it possible to regenerate the electrical energy stored in the battery from a charging current supplied to it from the outside.

 With regard to mobile phones, in particular, the autonomy (that is to say the possible duration of use of the device after a full charge of the battery) constitutes one of the functional characteristics of the device. most important to the user. Indeed, the fact that this autonomy is limited is the source of possible disadvantages for the user.

 The size of the battery is also an important characteristic of the device because it very sensitively conditions its total size.

 In recent times, significant progress has been made on the above characteristics, thanks to research efforts on battery chemistry. The latest generation of batteries sold are Lithium-ion (Li-ion) batteries. These batteries make it possible to store an amount of electrical energy, per unit of volume, which has more than doubled compared to the batteries of previous generations of the Nickel-Cadmium (Ni-Cd) type. Their self-discharge rate (i.e. discharge when the device is not used) is also much lower. On the other hand,

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 Li-ion batteries do not have a memory effect (this designation designates the impossibility of obtaining the full capacity of the battery if, for several discharge / charge cycles, it has been charged before being completely discharged ), as is the case with Ni-Cd batteries. The biggest disadvantage of Li-ion batteries is their cost, which remains relatively high. Located between the two types of battery above in terms of capacity in relation to size and in terms of cost, batteries of the Nickel Metal Hydride (Ni-MH) type have also been proposed. They are derived from Ni-Cd batteries, but have improved characteristics with a lower self-discharge rate and above all a lower memory effect.

 The aforementioned improvements in the batteries which deliver their supply current, added to the constant reduction in the current consumption of the electronic circuits which they incorporate, make it possible to increase the autonomy of the wireless electronic devices. Thus, for example, the autonomy of a mobile phone can today reach 5 to 10 days, depending on its use. This makes its use more comfortable since the frequency of the charges can be lower.

 On the other hand, this nevertheless turns out to be a source of possible inconvenience. Indeed, with a charging frequency as low as once every 5 to 10 days, for example, the user can more easily forget to charge the battery of his mobile phone. He may not be able to use his device when he wants to make or receive a call, due to the lack of sufficient battery charge. It is understood that this unpleasant situation can even constitute a danger in the event that the user has to make an emergency call, for example to notify the emergency services in the event of an accident or the like.

 Currently, a remedy for this drawback comes from a functionality of displaying the battery charge level on a screen of the device, which makes it possible to indicate to the user if a charge is necessary. Another remedy comes from the audible warning that is generated during communication when the battery charge level becomes so low that communication may be interrupted. These remedies are nevertheless imperfect, due to their lack of precision and / or their insufficiency in

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 actually prevent the above risks. Indeed, it is often when wanting to use his device or while using the device, that the user notices the complete discharge of the battery. Typically, it is when the user dials a number to make a call or when he answers a call, that the mobile phone turns off due to the depletion of the battery charge. As a result, he realizes that he can no longer use it when he needs it.

 The subject of the invention is a power supply device for a wireless electronic device, in particular but not exclusively a mobile phone, which makes it possible to reduce or even eliminate the aforementioned drawbacks due to the limited autonomy of this type of device.

 Indeed, the invention provides a power supply device capable of delivering a supply current for a wireless electronic device, in particular a mobile telephone or a cordless telephone, comprising a main power source and a power source electrically independent backup, and further comprising switching means for manually switching the device from a first operating mode in which the device delivers the supply current from the source of main power supply, in a second operating mode in which the device delivers the supply current from the emergency power source.

 The main and backup power sources are preferably batteries. For example, it is respectively a Ni-Cd or NiMH battery, and a Li-ion battery. By manual is meant in the sense of the present invention an operation which takes place, directly or indirectly, on the initiative of the user and following an action on his part.

 Commissioning of the backup battery by the user, after having noticed that the main battery is completely discharged when using or during the use of his device, allows him to be able to use it or continue to use it anyway. The long-awaited call can still be received. Likewise, an urgent call can still be given.

The user can also put the backup battery into service when the main battery is not yet fully discharged, in particular by

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 communication courses. It thus avoids the risk of communication breakdown.

 Other characteristics and advantages of the invention will become apparent on reading the description which follows. This is purely illustrative and should be read with reference to the accompanying drawings, in which there is shown: - in Figure 1: the diagram of a supply device according to the invention; - in Figure 2a and Figure 2b: diagrams showing the principle of the switching means of the device, respectively according to a first and according to a second embodiment; in FIG. 3: the diagram of charging means included in the device according to the invention; - in Figure 4: a mobile phone according to the invention provided with switching means according to the first embodiment mentioned above; and, - in Figure 5: a block diagram of a mobile phone according to the invention.

 The diagram in FIG. 1 represents a power supply device 100 according to the invention suitable for the power supply of a wireless device such as a mobile telephone.

 The device comprises a main battery 1, which is preferably a Ni-Cd battery or a Ni-MH battery due to the low cost of this type of battery, as well as a backup battery 2 which is preferably a Li- battery. ion due to the compactness of this type of battery and the absence of memory effect. These batteries 1 and 2 are connected between supply terminals 3 and 4 of the electrical device in which the device is integrated. More particularly, the negative terminals of batteries 1 and 2 are for example connected to terminal 4, the latter being intended to be connected to a low power supply terminal of the device. In addition, their positive terminals are connected to the power supply terminal 3 via switching means 5, the terminal 3 being intended to be connected to an upper power supply terminal of the device.

 The switching means 5 have the function of manually switching the device 100 from a first operating mode to a second operating mode. This passage is said to be manual, because it is the consequence of an effective action by the user. This action is symbolized in Figure 1

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 by a double arrow. The means 5 comprise an input 5a which is connected to the terminal 3 as well as two outputs 5b and 5c which are respectively connected to the positive terminal of the main battery 1 and to that of the backup battery 2.

 The batteries 1 and 2 are electrically independent, in the sense that, in established operation, they are not connected either in series or in parallel.

In fact, the device 100 delivers a supply current Is which flows from terminal 3 to terminal 4, this current Is being generated either from the main battery 1, or from the backup battery 2, depending on whether the switching means 5 cause the device to be in the first or in the second operating mode respectively. In other words, the switching means 5 select only one of the batteries 1 or 2 to be in service at a determined time. However, it is advantageous that the switching means 5 allow overlap during the transition between the first and the second operating mode, in order to prevent a break in the supply of the device (at least when the main battery 1 is not completely discharged).

 The device also comprises charging means 6 which have the function of managing the charge of the batteries 1 and 2. The charging means 6 comprise an input 6a and two outputs 6b and 6c. The input 6a is connected to an input 7 to receive a load current Ic coming from outside the device. This current can be generated by the device. Alternatively, it can be generated by a charging device external to the device. In this case, the input 7 is connected to a power connector, to receive a charging current Ic coming from outside the device in which the device 100 is mounted. The current Ic comes for example from a charging device external to the device, which is connected to said connector 7 via a complementary connector 71. Conventionally, such a charging device comprises a voltage transformer for converting a mains voltage, for example equal at 110 volts or 220 volts at a low voltage, for example equal to 6 or 9 volts.

 The output 6b of the charging means 6 is connected to the positive terminal of the main battery 1 in order to deliver a charging current Ic1 to it. Similarly, the output 6c of the charging means 6 is connected to the positive terminal of the backup battery 2, here via an adaptation module 8, to deliver a current of

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 load Ic2. Such an adaptation module 8 may be necessary when the batteries 1 and 2 are of different respective types as is the case in the preferred embodiment considered here, and that in addition the charging current Ic is only suitable for charging one of the batteries and not charging the other. Indeed, the charge currents Ic1 and Ic2 must then be different (for example as regards the value or the waveform of these currents) and in addition, the charge voltage which is applied to the terminals of the batteries 1 and 2 must also comply with certain constraints (for example it must be constant, and / or limited to a maximum value) which depend on the type of battery. Of course, the adaptation module 8 can be of the type suitable for, and be arranged for the generation of the current Ic2 (as in the example shown here) or for that of the current Ic1, from the charging current Ic. In certain cases, it is also possible to provide two such adaptation modules, one for generating each of the currents Ic1 and Ic2. In the example shown here, the adaptation module 8 can be produced by a commercially available component called a Li-ion battery charger.

 The charging means 6 have the function, in combination with the adaptation module (s) 8, of adapting and orienting the charging current Ic towards one and / or the other of the batteries. 1 and 2, in the form of the charging currents respectively Ic1 and / or Ic2 suitable for charging these batteries.

 FIG. 2a shows a first embodiment of the switching means 5.

 In this first embodiment, the switching means 5 comprise a two-position switch 50. Such a switch can be operated manually by the user to move, mechanically, from a first determined position to a second determined position, and vice versa. It comprises three contacts 51, 52 and 53 respectively connected to the input 5a, to the output 5b and the output 5c of the switching means 5. In said first determined position of the switch 50, the contacts 51 and 52 are connected together , so that the input 5a of the switching means 5 is connected to their output 5b. The main battery 1 is then in service. In said second determined position of the switch 50, the contacts 51 and 53 are connected together so that the input 5a of the switching means

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 5 is connected to their output 5c. It is then the backup battery 2 which is in service.

 To go from the first operating mode in which it is the main battery 1 which is in service in the second operating mode in which it is the backup battery 2 which is in service, the user operates the switch 50 in a direction determined to bring it from the first of the above-mentioned positions (that shown in FIG. 2a) into the second of the above-mentioned positions.

 In this first embodiment, the switching means 5 also make it possible to manually return the device from the second operating mode to the first operating mode. To this end, the user operates the switch 50 in the opposite direction to the determined direction mentioned above.

 FIG. 2b shows a second embodiment of the switching means 5.

 In this second embodiment, the switching means 5 comprise a contactor 55 of the push button type, a bistable element 56 of the rocker type, and a two-position controlled switch 57 of the bistable relay type or the like. A first terminal of the contactor is connected to the output 5c of the switching means 5 to receive the supply voltage delivered by the backup battery 2. Thus, the operation of the switch 5 is possible even in the event of a complete discharge of the main battery 1.

The second terminal of the contactor 55 is connected to a control input C of the flip-flop 56. A reset input R of the flip-flop 56 can also receive a reset signal RST. In addition, an output S of the flip-flop delivers a control signal CTRL1.

 The switch 57 comprises three contacts 58, 59 and 60. The contact 58 is connected to the input 5a of the switching means 5. The contacts 58 and 59 are connected, respectively, to the outputs 5b and 5c of the switching means 5. In a first determined position of the switch 57 (that shown in the figure), the contacts 58 and 59 are connected together. The device 100 is then in the first mode of operation, in which the supply current Is is delivered from the main battery 1.

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In a second determined position of the switch 57, the contacts 58 and 60 are connected together. The supply device is then in the second operating mode, in which the supply current Is is delivered from the backup battery 2. The switching of the switch 57 from the above-mentioned first position to the above-mentioned second position, or vice versa, is electrically controlled by the control signal CTRL1. In one example, when this signal is in the low logic state (logic state 0) the switch is in said first position, while when this signal is in high logic (logic state 1) the switch 57 is in said second position.

 The passage of the control signal CTRL1 from logic state 0 to logic state 1 is controlled by a positive pulse received on input C of the flip-flop 56. This pulse occurs when the user presses the push button 55. The return of the signal CTRL1 to the logic state 0 is caused by a positive pulse on the input R of the flip-flop 56, that is to say on a rising edge of the aforementioned signal RST. According to a specific feature of the embodiment of FIG. 2b compared to that of FIG. 2a, the switching means 5 according to the second embodiment in accordance with FIG. 2b allow the device 100 to be automatically brought back from the second operating mode to the first operating mode, by generating a positive pulse of the RST signal. Such an impulse is generated when the apparatus is started up, so that the supply device is by default in the first operating mode.

 In the first as in the second embodiment of the switching means 5 described above, the switch 50 respectively the contactor 55 are advantageously arranged so that they can be operated by the user but also so as to avoid an involuntary operation . In the case where the device is integrated into a mobile phone, these members are for example arranged in a recess of the mobile phone case, preferably on one side of it, and not on the bottom of the case where an accidental operation is more likely.

 In FIG. 3, there is shown schematically an embodiment of the charging means 6.

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 These charging means 6 comprise a two-position switch 67 having three contacts 61, 62 and 63. The contact 61 is connected to the input 6a of the charging means 6 via a shunt resistor 64 to which we will return later. The contacts 62 and 63 are connected, respectively, to the outputs 6b and 6c of the charging means 6. In a first determined position of the switch (that shown in the figure), the contacts 61 and 62 are connected together. It is then the main battery 1 which is charged (generation of the charging current Ic1 from the charging current Ic). In a second determined position of the switch 67, the contacts 61 and 63 are connected together. The backup battery 2 is then charged (generation of the charging current Ic2 from the charging current Ic). The switching of the switch 67 from the first to the aforementioned second position, or vice versa, is electrically controlled by a control signal CTRL2.

 The charging means 6 also include a control module 66 and a comparator 65. A first input of the comparator 65 receives a reference voltage Vref. A second input of comparator 65 is also connected to the common node between the shunt resistor 64 and the contact 61 of the switch 67. Thus connected, the comparator 65 compares the potential on this node with the reference voltage Vref to output a signal COMP which can be either in logic 0 or in logic 1.

The signal COMP is supplied at the input of the control module 66. The latter delivers at the output, on the one hand the aforementioned signal CTRL2 and on the other hand the signal RST presented above (when the switch 5 conforms to the second mode of embodiment described above with reference to FIG. 2b).

 The operation of the charging means 6 is as follows. The control signal CTRL2 is by default in logic state 0. In one example, it then controls the switch 67 so that it is in said second position mentioned above, in which the contacts 61 and 63 are linked together. Thus, as soon as a charging current Ic is supplied to the power supply device 100 via the input 7 (FIG. 1), the charging means 6 generate the charging current Ic2 of the backup battery 2 from this charging current Ic received from outside the device 100.

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 When the charging of the backup battery 2 is completed, the charging current Ic decreases, or even vanishes, or even reverses. This cancellation or this reversal of the charging current Ic results in a reduction, in a cancellation or in a reversal of the voltage across the shunt resistor 64. This is detected by the comparator 65, the reference voltage Vref having a value ad-hoc for this purpose. The signal COMP then changes logic state. It goes to logic state 1. This change of logic state of the signal COMP causes the control module 66 to cause the change of logic state of the control signal CTRL2 which then goes to logic state 1. This change of the logic state of the signal CTRL2 switches the switch 67 to said first position mentioned above, so that the contacts 61 and 62 are connected together. When the main battery 1 is discharged, the charging current Ic1 is then generated from the charging current Ic received from outside the device 100.

 When the switching means 5 conform to the second embodiment described above with reference to the diagram in FIG. 2b, the change in the logic state of the signal COMP further causes the control module 66 to generate a positive pulse of the signal RST . It will be recalled that this signal is applied to the flip-flop 56 of the switching means 5 to cause the automatic return of the device 100 to its first operating mode. Thus, the device is returned to the first operating mode as soon as the main battery 1 is (at least partially) charged.

 The realization of the control module 66 is within the reach of a person skilled in the art. In one example, it can be produced from discrete components. It can also be integrated in the form of a software module into a program executed in a computer such as a microprocessor or a microcontroller.

 According to possible variants, the main battery 1 can be charged first, and then the backup battery, or the two batteries can be charged at the same time. In other words, the charging means 6 make it possible to charge the main battery and the backup battery, either sequentially (starting with one or the other), or simultaneously.

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 The embodiment described above with reference to FIG. 3, according to which the charging means 6 make it possible to charge the batteries sequentially starting with the backup battery 2, is however advantageous for the following reason. This embodiment makes it possible to have the backup battery 2 as quickly as possible with a maximum state of charge. As this battery is preferably a Li-ion battery, which has no memory effect, its charge can indeed be rapid since it is not useful to discharge it completely before initiating a charge cycle. We can then take more time to charge the main battery (which is preferably a Ni-Cd or Ni-MH battery, with memory effect), by performing a discharge cycle preceding a charge cycle.

 The diagram in FIG. 4 represents a mobile telephone 200 according to the invention and also makes it possible to illustrate an exemplary embodiment of the switching means 5 according to the first embodiment described above with reference to the diagram in FIG. 2a.

 The mobile telephone 200 includes a housing 40 which houses an antenna 41 for the transmission and reception of a radio signal. It further includes a display screen 95 for displaying the called or calling number, the name of the called or calling party, functional symbols, menus for command entry, etc.

 The mobile telephone 200 also includes a keyboard 94 provided with various keys. It is in particular a key 42 for switching the mobile telephone on and off, keys such as 43 for dialing telephone numbers and / or for entering symbols and / or characters, of a key 43 to validate the dialing of a telephone number called and / or to validate any other command, of keys such as 45 to navigate within menus displayed on the screen 95 for the selection of 'An order.

 The housing 40 of the mobile phone 200 also houses a power supply device (not visible in the figure) such as the device 100 described above.

 According to the invention, the keyboard 94 of the mobile telephone further comprises a key 46 called the emergency call key in the following. This key allows, when pressed by the user, on the one hand to put the

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 supply device 100 for mobile phone 200 in its second operating mode in which the supply current is generated from the backup battery 2. It also makes it possible to call a determined number called a call number emergency in the future. Such a number can for example be an emergency number such as the number of the police, fire brigade or any other emergency service. In the case of a GSM phone (Global System for Mobile) it is for example the number 112. It can also be a number recorded in advance by the user and stored in a memory of the phone. mobile. This number can be that of a person or organization that the user wishes to call in an emergency.

 Advantageously, the user can then, in an emergency, cause the emergency number to be called without this risk of being prevented by a possible complete discharge of the main battery 1 of the mobile phone. The user has no need to worry about the state of charge or discharge of the main battery. In this sense, the emergency key 46 according to the invention, in combination with a power supply device 100 as described above, transforms the user's mobile phone into an effective and reliable security accessory.

 FIG. 4 also makes it possible to illustrate an advantageous embodiment of the supply device 100 according to the invention. In fact, when the supply device 100 comprises switching means 5 according to the first embodiment described above with reference to FIG. 2a, and in particular a two-position switch 50 of the slide type, on the one hand , as well as charging means provided with a connector as an input 7 for receiving a charging current from the outside, on the other hand, the switch 50 and the connector 7 can advantageously be arranged in the following manner.

 The switch 50 is arranged relative to the connector 7 so that when it is in the aforementioned second position (that in which the supply device is in the second operating mode), it is returned to the aforementioned first position (the one in which the device 100 is in the first operating mode) when a connector

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 71 complementary to the connector 7 is introduced into the latter to deliver the charging current Ic.

 This object is achieved, for example, by means of a finger 72 of a housing 70 which supports the connector 71. As shown in FIG. 4, this finger 72 can then penetrate a groove 80 of the housing 40 of the mobile telephone forming a slide inside which an operating member of the switch 50 can circulate, between its first and its second determined position. The groove 80 is through, near the connector 7. In the example shown, said first position corresponds to a position of the operating member in the bottom of the groove 80 (above, in the figure) while said second position corresponds to a position of the actuator at the entrance to the groove 80 (below in the figure). The finger 72 can then push this operating member to return the switch 50 from said second position to said first position.

 In this way, the supply device 100 is mechanically returned to the first operating mode when the batteries 1 and 2 are recharged. This ensures that the user does not inadvertently leave the device in the second operating mode.

 In Figure 5, there is shown a block diagram of a mobile telephone 200 according to the invention.

 The mobile telephone 200 comprises a microprocessor 90 which is supplied by a supply device 100 as described above. The microprocessor 90 is also connected to the keyboard 94 and to the screen 95 to provide the interface with the user. The telephone further comprises a memory 91 such as a SIM (Subscriber Identity Module) card in which, in particular, the emergency call number mentioned above is saved.

The telephone further comprises a modem 92 for transmitting and receiving data via a radio channel respectively to or from a base station. The memory 91, the modem 92 and the power supply device are controlled by the microprocessor 90.

 In particular, the microprocessor executes a program, which causes the device to be placed in the second operating mode and the number

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 emergency call is then automatically called, when the user presses the emergency call key 46 (FIG. 4) on the keyboard 94.

Claims (12)

1. Power supply device (100) capable of delivering a supply current (Is) for a wireless electronic device, in particular a mobile telephone or a cordless telephone, comprising a main power source (1) and a source emergency power supply (2) electrically independent of each other, and further comprising switching means (5) for manually switching the device from a first operating mode in which the device delivers the current d power (Is) from the main power source, in a second mode of operation in which the device delivers the power supply from the emergency power source.  2. Device according to claim 1, wherein the switching means (5, Figure 2a) further allows to manually return the device from the second operating mode to the first operating mode.  3. Device according to claim 1, wherein the switching means (5, Figure 2b) allow to automatically return the device from the second operating mode to the first operating mode.  4. Device according to any one of the preceding claims, further comprising charging means (6) allowing the charging of the main power source (1) and the charging of the emergency power source (2), either simultaneously or sequentially, from a load current (Ic) received from outside the device.  5. Device according to claim 4, in which the charging means (6) comprise means for detecting the decrease, cancellation or reversal of the charging current () c) and for bringing the device back from the second operating mode in the first operating mode in case of <Desc / Clms Page number 16>  detection of this reduction, this cancellation or this reversal respectively.  6. Device according to claim 4 or claim 5, wherein, the main power source (1) and the emergency power source (2) being of respective types different from each other, and the charging current (Ic) received from outside the device being only suitable for charging a power source of one of these types only, the charging means comprise at least one adaptation module (8) to adapt the load current (Ic) to the load of the power source of the other of these types.  7. Device according to any one of claims 4 to 6, in which the charging means (6) comprise a connector (7, FIG. 4) for receiving the charging current (1c) from outside the electrical appliance .  8. Device according to claim 2 and claim 7, wherein the connector (7) and the switching means (5) are arranged such that the switching means can be actuated by a finger (72) of a housing (70) supporting a connector (71) complementary to said connector (7) when this additional connector is inserted in the connector (7), so as to mechanically return the device from the second operating mode to the first operating mode.  9. Device according to any one of the preceding claims, in which the main power source (1) is a NickelCadmium (Ni-Cd) or Nickel-Metal-Hydride (Ni-MH) battery. 10. Device according to any one of the preceding claims, in which the emergency power source (2) is a Lithium-ion (Li-ion) battery.  11. Mobile telephone (200) comprising a power supply device according to any one of the preceding claims. <Desc / Clms Page number 17>  12. Mobile phone according to claim 11, comprising an emergency call button (46) and means for, if pressed on this emergency call button, on the one hand automatically switch the device power supply of the first operating mode in the second operating mode, and on the other hand then automatically call an emergency call number.