JPH08500959A - Electronic device having an internal charge regulator for controlling the application of charging current and related methods - Google Patents

Abstract

(57) [Summary] An electronic device (10), such as a wireless telephone, is connectable to a variable level power supply (16). The circuitry of the electronic device (10) generates a power control signal to select the power level of the signal generated by the variable level power supply (16). If the electronic device (10) has a rechargeable battery pack carried with it, the variable level power supply (16) is a battery cell (70) of the battery pack when the transmitter circuit of the wireless telephone is not operating. To work to recharge. When the radio telephone transmitter circuit is operating, the battery cells (70) of the battery pack are not recharged and the power level of the signal generated by the variable level power supply (16) powers the radio telephone transceiver circuit. It becomes the level to do.

Description

Description: Electronic device having an internal charge regulator for controlling the application of charging current and associated method BACKGROUND OF THE INVENTION The present invention generally relates to an electronic device that can be powered by a rechargeable power source. And, more specifically, an electronic device capable of being connected to an external power source capable of supplying operating power for powering the electronic device and also for recharging the rechargeable power source of the electronic device, and Related methods, regarding. Many electronic devices are constructed in a design that allows them to be powered by a battery of one or more battery cells. In some cases, battery power is used to power the electronic device if the electronic device is not or cannot be placed near a permanent or other fixed, power source. Required to do. In other cases, the power cable needed to interconnect the electronic device to a permanent or other fixed, power source is not required, so the electronic device may be added to increase the portability of the device. Battery power is used to supply power. Typically, one or more battery cells that make up the battery power source used to power the electronic device are carried directly with or contained within the electronic device. However, since the battery power supply can store only a limited amount of energy, the power supply of the electronic device by the battery power supply is limited by the energy storage capacity of the battery power supply. Powering the electronic device from the battery power source causes discharge of the stored energy of the battery power source. Once the stored energy of the battery power source has been discharged above a certain level, replacement of the battery power source is necessary to allow continued operation of the electronic device. Increasing the energy storage capacity of a battery power supply increases the size (and weight) of the power supply, for example by increasing the number of battery cells that make up such a power supply. Increasing the energy storage capacity of a battery power source in such a manner reduces the portability of the electronic device when the battery power source is carried with the electronic device. Therefore, when designing a battery power supply, a trade-off is made between increased energy storage capacity and reduced portability of electronic devices carrying such battery power. A portable or portable wireless telephone is one such electronic device that is typically powered by a battery power source. Battery power supplies are typically dimensioned and weighted to be carried directly with the radiotelephone and not unduly constraining the portability of the radiotelephone. The radiotelephone includes radio transceiver circuitry that includes transmitter circuitry and receiver circuitry operable to transmit and receive modulated signals, respectively. In typical operation of a radiotelephone, its receiving circuitry is constantly powered while waiting to receive a signal indicative of an incoming call to the radiotelephone. Thereafter, the transmitter circuitry portion of the radiotelephone is also powered to allow the modulated signal to be transmitted therefrom. A radiotelephone operable in many cellular communication systems is configured to transmit a modulated signal therefrom and also simultaneously receive a modulated signal transmitted thereto (modulated signal transmitted by the radiotelephone). And the modulated signal sent to the radiotelephone is sent on a separate frequency channel). A wireless telephone operating in another cellular communication system is configured to transmit and receive modulated signals during non-simultaneous periods and during two-way communication with the wireless telephone, the receiving circuitry and The transmitter circuitry is powered during non-simultaneous periods. The time during which power is supplied to the receiving circuit section of the wireless telephone while waiting for the transmission of a signal indicating an incoming call is hereinafter referred to as the time during which the wireless telephone is in the "standby" mode. (Of course, a user of a wireless telephone often powers the wireless telephone only when the user wants to initiate and then make a telephone call, and at other times powers the wireless telephone. It should be noted that it is not possible and that the radiotelephone is not powered in order to receive the signal transmitted to it, in other words the user of the radiotelephone is transmitted to it. It is possible to choose not to operate the radiotelephone in "standby" mode to receive incoming calls and to power the radiotelephone only during the time the user initiates the telephone call.) Generally, the transmission circuitry of the radiotelephone. Is greater than the amount of energy required to operate the receiving circuitry. Also, since real devices have less than ideal efficiencies, some of the energy supplied to the radiotelephone is converted to heat energy, which results in heat buildup of the radiotelephone. As more energy is required to operate the radio telephone's transmitter circuitry, a correspondingly greater amount of heat is generated during operation of the radio telephone's transmitter circuitry than if only the receiver circuitry was operational. There is an occurrence. Rechargeable battery power sources have been developed and are commercially available. Some of such commercially available rechargeable battery power supplies have configurations designed for use in powering wireless telephones. Using a rechargeable battery power source is convenient because the rechargeable battery can be recharged by supplying the charging current generated by the power source thereto. Once recharged, the rechargeable battery power source can be reused. Some configurations of rechargeable battery power supplies can be recharged and reused up to 500 times and more than 500 times. As mentioned previously, battery power supplies typically consist of one or more battery cells. The cells are connected in series (or other) connection scheme and are typically housed in a common housing. The housing, together with the battery cells, constitutes a battery power source, which is often also referred to as a battery pack. For simplicity, such structures are also generically represented by the general term "battery". In this specification, such simplified terminology is often used. The battery cells of a rechargeable battery power source are made of a variety of different materials of construction. For example, some rechargeable battery cells include lithium (Li) material, nickel-cadmium (Ni-Cd) material, or nickel metal hydride (NiMHO). ₂ ) Can be composed of materials. Battery cells composed of these different materials exhibit different properties during their charging. Battery chargers are also commercially available to allow recharging of rechargeable batteries. A battery charger consisting of such a battery charger is typically When properly connected to a charger to receive operating power, It consists of a power supply that provides operating power to recharge the rechargeable battery power supply. The energy of the operating power supplied to the rechargeable battery power supply is converted into chemical energy and stored by the rechargeable battery cells of the battery power supply. The rechargeable battery cell may be fully recharged by supplying operating power to the battery cell over a period of time. However, As mentioned before, real devices have less than ideal efficiency, so A portion of the energy supplied to the battery cells is converted to heat energy, which causes the battery cells to heat up. Some battery chargers are of a structural type that allows both the electronic device and the battery power source to receive operating power. Such a battery charger not only provides operating power to recharge a rechargeable battery of a battery power source, but also provides operating power to enable operation of the electronic device. For example, Battery chargers of the structural type are available that allow the radiotelephone as well as the rechargeable battery pack to receive operating power to recharge the battery cells of the battery pack and also enable operation of the circuitry of the radiotelephone. However, As I mentioned before, In a real device, heat is generated as a by-product of the operation of the radiotelephone circuit. Also, Heat is also generated as a by-product of the process of recharging battery cells of battery power. Again, as I said before, A greater amount of energy is required to operate the transmitter circuitry of the radiotelephone circuitry. Some of the operating power supplied to wireless phones is converted to heat energy, And since thermal energy is also generated during recharging of the rechargeable battery cells of the battery pack, Operating power for recharging the battery cells of the battery pack and also an electronic device, Wireless phone here, When operating power is supplied for both to operate each part of the circuit of And especially during the time when the transmission circuit section of the wireless telephone can operate, An excessive amount of heat rise of wireless telephones can occur. Therefore, What is needed is a means to provide operating power to an electronic device that includes a rechargeable power source, but to prevent excessive heat buildup as a result of supplying operating power to the electronic device. SUMMARY OF THE INVENTION Therefore, The present invention is an apparatus that overcomes the problems associated with existing technology, And related methods, I will provide a. The present invention preferably provides an electronic device including a rechargeable power source, The electronic device is connectable to a variable level power supply that provides operating power to recharge the rechargeable power source and to provide operating power to operate the electronic circuitry of the electronic device. The present invention has further advantages and features, Those details will become more apparent with reference to the following detailed description of the preferred embodiments. Therefore, According to the present invention, An electronic device that is releasably connectable to a variable level power supply, And related methods are disclosed. The electronic device is operable to receive operating power at any of at least two power levels generated by the variable level power supply. The electronic device comprises a connection element that enables a detachable connection with a variable level power supply. The connecting element comprises at least a first connecting element and a second connecting element, The first connecting element enables a variable level power supply to be connected to receive operating power. A rechargeable power supply is coupled to receive a charging signal depending on the time that the variable level power supply is connected to the first of the connection elements and to any of the at least two power levels. Generate operating power at a first power level. An electronic circuit coupled to alternately receive either operating power generated by a variable level power supply provided at said first connecting element or power generated by energy stored by a rechargeable power supply. There is. A control circuit is connected to the electronic circuit and is operative to generate a power supply control signal for supplying a second one of the connecting elements; The power supply control signal is at least a first signal level that causes the operating power of the variable level power supply to be a first one of the at least two power levels, or the operating power of the variable level power supply is the at least two power levels. This is the second signal level that causes it to be the second of the power levels. BRIEF DESCRIPTION OF THE DRAWINGS The present invention is better understood by reference to the following description in light of the accompanying drawings, In the drawing, Figure 1 FIG. 3 is a block diagram of an electrical device according to a preferred embodiment of the present invention connected to a variable level power supply. Figure 2 Similar to that of FIG. 1, but FIG. 3 is a block diagram illustrating a preferred embodiment of the present invention connected to a variable level power supply. FIG. A partial block showing a charge regulator forming part of the electronic device of Figure 1 and the wireless transceiver of Figure 2; It is a partial circuit diagram. FIG. Of the preferred embodiment of the present invention, Similar to the wireless transceiver shown in block form in FIG. 3, 1 is a schematic diagram of a cellular radiotelephone. Figure 5 3 is a flow diagram showing method steps of an algorithm executable by a control circuit forming part of the wireless transceiver of FIG. 2 and the electronic device of FIG. FIG. 4 is a flow chart showing the method steps of the method of the preferred embodiment of the present invention. Description of the Preferred Embodiment As mentioned above, Portable electronic devices are often powered by a rechargeable power source. When the stored energy from the rechargeable power source is exhausted, A battery charger is used to recharge the rechargeable battery cells of the rechargeable power source. Allows the portable electronic device to be placed with a rechargeable power supply carried with it, There are several configurations of battery chargers available that allow operating power to be provided to both the rechargeable battery cells of the rechargeable power source and also to the circuitry of the electronic device. However, Since the power transfer between the battery charger and the electronic device is not completely efficient, An energetic portion of the operating power generated by the battery charger is converted to heat energy, The heat energy raises the temperature of the electronic device during its dissipation. When the operating power generated by the battery charger is used together to recharge the battery cells of the rechargeable power source and also to operate the circuitry of the electronic device, Thermal energy is generated during the operation of both processes. In the particular case where the electronic device comprises a wireless telephone operable in a cellular communication system, The battery charger provides operating power to recharge the rechargeable battery cells of the rechargeable power supply carried with the wireless telephone while also enabling operation of the transmitter and receiver circuitry of the wireless telephone. Is configured to provide operating power for As I mentioned before, Operating the transmitter circuitry of a wireless telephone requires more power than operating its receiver circuitry. Therefore, If the wireless telephone (or other wireless transceiver) with a rechargeable power source is adapted to recharge the battery cells of the rechargeable power source and the wireless telephones operate simultaneously, More power is required during the time the radiotelephone operates to transmit the modulated signal than during the time it operates to only receive the modulated signal. (This, as I said before, Radiotelephones often operate in a "standby" mode in which only the receiver circuitry of the radiotelephone operates while waiting to receive a modulated signal indicative of an incoming telephone call. Two-way communication should take place between the wireless telephone and the remote location, Or done, Only during the time should the transmitter circuitry part of the radiotelephone be operational. ), But Since more power is required during the time when the transmitting circuit portion of the wireless telephone operates, than during the time when only the receiving circuit portion of the wireless telephone operates. More heat energy is produced during the time the transmitter circuitry portion of the wireless telephone operates. A battery charger that operates to allow recharging of a battery cell of a rechargeable power source and also to power the circuitry of an electronic device has a power level that enables both such recharging and such operation. Must generate electricity at. A battery charger operating to generate a charging signal of only a single power level is a signal at a power level capable of simultaneously recharging battery cells of a rechargeable battery power source and also operating electronic circuitry of an electronic device. Must occur. Even if the electronic device is not working, Such battery chargers generate a charging signal at the same power level as the charging signal generated when the circuitry of the electronic device is operating. The power otherwise used to power the circuitry of the electronic device is not used for any useful purpose, And, instead of, It is converted into heat energy. In the particular example where the electronic device comprises a wireless telephone, A battery charger can be constructed that is operable to recharge the battery cell of a rechargeable power supply carried with the wireless telephone and also power its transceiver circuitry. However, When such a battery charger operates to generate a charging signal at a single power level only, The power level is at the same time, It must be large enough to allow recharging of the battery cells of the rechargeable power source and operation of both the receiving and transmitting circuitry of the wireless telephone. Radio telephone receiver circuitry is often powered in a "standby" mode of operation, On the other hand, the transmission circuit section is supplied with electric power only during the time when two-way communication is performed with the remote site. Two-way communication is performed in the transmission circuit section of the wireless telephone, Or because it only works during the time it should be done, In many cases, Where the rechargeable power supply along with the wireless telephone is configured to receive a charging signal generated by a battery charging device that operates to generate a charging signal at a single power level only, The radiotelephone is even more susceptible to overheating due to the conversion of excess power into heat energy. It would be advantageous to have a battery charging device that operates to generate a variable power level charging signal in response to the power demand of an electronic device having a rechargeable battery power source. In the particular case of wireless transceivers, such as wireless telephones, A battery charger that operates to prevent overheating of the transceiver when its transmitter circuitry is operating is particularly advantageous. First of all, if we move to the block diagram of FIG. Collectively referred to by reference numeral 10, The electronic device of the preferred embodiment of the present invention is disposed in releasable connection with the variable level power supply 16. The variable level power supply 16 is Shown here as a plug connector represented by the plug terminals contained in the rectangle shown by the dotted line, In the connection elements 34 and 40, Respectively, It is connected to the electronic device 10 by lines 22 and 28. The variable level power supply 16 is next, It can be connected to a traditional household power source (or by plug connector 36) or any other suitable power source. Variable level power supply 16 operates to generate a charging signal on line 22 that is one of at least two separate power levels. (In yet another embodiment of the present invention, Power supply 16 operates to generate a charge signal on line 22, which is one of a number of levels between maximum and minimum charge levels. The line 46 of the electronic device 10 is coupled to receive the charging signal generated on the line 22 by the variable level power supply 16. Line 46 is next, Providing operating power to the electronic circuit 52 of the electronic device 10 when the power supply 16 is connected to the connecting element 34 by line 22 to provide operating power. The line 46 is further connected to the charge regulator 58, The charge regulator 58 regulates the value of the charge signal provided thereto by line 46 and generates a regulated charge signal on line 64, The conditioned received signal is coupled to a rechargeable battery power source 70. The power supply 70 consists of one or more rechargeable battery cells. With such a connection, The charge signal generated by power supply 16 on line 22 is provided to rechargeable battery power supply 70 to recharge the rechargeable battery cell. The battery cells of the rechargeable battery power supply 70 convert the energy generated by the power supply 16 and conditioned by the charge regulator 58 into chemical energy, The chemical energy is stored in the battery cells of the rechargeable battery power supply. The battery power source 70 is connected to the electronic circuit by the line 76. If the power source 16 is not connected to the electronic device 10 to provide a charging signal thereto, The stored energy of battery power source 70 is used to power circuit 52 to enable operation of electronic device 10 therewith. However, And as I said before, Powering the circuit 52 with the stored energy of the battery power source 70 discharges the stored energy of the battery power source. Once the stored energy of the battery power source 70 is exhausted below a certain level, A battery cell of a battery power source must be recharged by supplying a charging current to the battery power source to recharge the battery cell. The control circuit 82 also forms part of the electronic device 10. The control circuit 82 is connected by line 88 to the electronic circuit 52 and by line 94 to the charging regulator 58. The control circuit 82 is further connected to the connecting element 40 by a line 100, This allows the control circuit 82 to connect to line 28, The line 28 is next, It is connected to the variable level power supply 16. Also, The control circuit 82 is preferably connected by line 106 to the rechargeable battery power source 70. The electronic device 10 further includes an input element 112 connected to the electronic circuit 52 by a line 118. Similarly, For example, Composed of light emitting diodes, The display element 124 also Here by line 128, It is connected to the electronic circuit 52. The user of the electronic device 10 may be activated (eg, by The device 10 is operated (by actuating an off / on actuation switch, which may form part of the input element 112). The portion of electronic circuit 52 that operates in response to such an input has its circuit elements Connected to receive operating power on line 46 generated by power supply 16 when connected to device 10 by connection element 34, Alternatively, Otherwise, Connect to battery power 70. When the electronic circuit 52 is operating, A signal indicative of such operation is provided by line 88 to control circuit 82. In response to the signal provided by line 88, The control circuit 82 generates a signal of the first signal value on the line 100, The signal is next, It is supplied to line 28 by connection element 40 as it is supplied to variable level power supply 16 when connected to connection element 40 by line 28. vice versa, If the electronic circuit 52 should not be operated, A signal (or no signal condition) of the second signal value is generated on line 88 and provided to control circuit 82. In such cases, The control circuit 82 produces a signal (or no signal condition) on the line 100 at a second signal level value, It can likewise be supplied to the variable level power supply 16. When the variable level power supply 16 is connected to the connection element 40, The power supply 16 thereby receives on line 28 a signal indicating whether or not the electronic circuit 52 is operating. If the electronic circuit 52 is operating and the power supply 16 is connected to the electronic device 10, The charging signal generated on line 22 by power supply 16 must be of a power level large enough to power circuit 52. vice versa, If the electronic circuit 52 should not be operational, The power supply 16 need not generate a power level charging signal that causes the operation of the circuit 52. Since the charging signal generated by the power supply 22 is further used to recharge the battery cells of the battery power supply 70, The charging signal generated by the power source 16 must be at a power level to properly recharge the battery cells of the battery power source. Operative to adjust the level of the charging signal generated by power supply 16 on line 22; Charge regulator 58 produces a regulated charge signal on line 64, The adjusted charging signal is supplied to the battery cell of the battery power source 70. The control circuit 82 is further operative to generate a control signal on line 94 to control the level of the regulated charge signal provided to the battery cells of the battery power source. The value of the control signal generated by control circuit 82 on line 94 is At least partially It can be determined by the measured voltage level measured at the battery power source 70 and supplied by line 106 to control circuit 82. (The measured voltage level at power supply 70 can be measured by any conventional method. ) In a first preferred embodiment of the invention, When the power supply 16 is connected to the electronic device 10 by the connecting elements 34 and 40, The power supply 16 produces a low power level signal on the line 22 during the time that the electronic circuit 52 operates. Also, The power supply 16 has the electronic circuit 52 not operating, Or generate a high power level signal on line 22 when it should not operate. Whether the electronic circuit 52 is not operating, Or if it shouldn't work, The signal generated on line 22 by power supply 16 is at a power level high enough to recharge the battery cells of battery power supply 70. In another preferred embodiment, The power supply 16 operates in a similar manner, but The signal produced on line 22 further depends on the amount of charge stored in battery power supply 70. (Also, The amount of charge stored in the power supply 70 is proportional to the voltage level applied to the power supply 70. ) The value of the signal generated by control circuit 82 on line 100 is At least partially If the value depends on the value of the signal applied to the control circuit 82 by line 106, Variable level power supply 16 produces a signal on line 22 at a level between the two power levels mentioned above, The particular power level of the signal depends on the amount of charge already stored in the battery cells of battery power supply 70. However, In any of the examples The power level of the signal generated by the variable level power supply 16 on line 22 is selected to be a value that minimizes excessive heat generation during the operation of electronic circuitry or the recharging of battery cells of battery power supply 70. It Next, moving to the block diagram of FIG. Of the preferred embodiment of the present invention, Collectively referred to by reference numeral 210, Wireless transceiver, Wireless phone here, It is shown. The wireless telephone 210 corresponds to the electronic device 10 of FIG. Variable level power supply 216 is releasably connected to wireless telephone 210 by lines 222 and 228, The lines 222 and 228 are represented by plug terminals arranged in a rectangle indicated by a dotted line, Shown as being a plug connector, It is connected to the connection elements 234 and 240. The variable level power supply 216 is next, It can be connected to a traditional household power supply or a car power supply (by connection by plug connector 236). Power supply 216 operates to generate a selected level of charging signal on line 222. The line 246 of the wireless telephone 210 is a connection element 234 and a transceiver circuit of the wireless telephone 210, Here, it is shown as including the receiving circuit unit 250 and the transmitting circuit unit 252, Interconnect with. When the power supply 216 is connected to the connection element 234 of the wireless telephone 210, The signal generated by the power supply 216 is supplied to the receiving circuit unit 250 and the transmitting circuit unit 252, and the operating power for operating the circuit units 250 and 252 can be supplied. Charge regulator 258 also forms part of radiotelephone 210 and is coupled to line 246 to receive the signal generated by power supply 216 when power supply 216 is connected by line 222 to connecting element 234. Charge regulator 258 operates to regulate the value of the signal provided thereto by line 246 and generate a regulated charge signal on line 264, The conditioned charge signal is provided to a rechargeable battery power source 270 to allow recharging of that battery cell. The rechargeable battery power source is connected to the receiving circuit section 250 and the transmitting circuit section 252 by the line 276. If the variable level power supply 216 is not connected to the wireless telephone 210, The energy stored in the battery cells of rechargeable battery power source 270 is used to provide operating power to operate receiver circuitry 250 and transmitter circuitry 252. The control circuit 282 connects the receiving and transmitting circuit sections 250 and 252 by a line 288 to To the charge regulator 258 via line 294, To the connecting element 240 by line 300, It is then connected by line 306 to a rechargeable battery power source 270. The signal provided by line 288 to control circuit 282 indicates the time that said circuitry 250 and 252 are in operation. (As I mentioned before, During operation of the wireless telephone 210, The receiver circuitry 250 is often powered in "standby" mode, The transmitter circuitry of the radiotelephone typically operates only during the time two-way communication is to be performed by the radiotelephone. ) If only the receiving circuit unit 250 is operable or neither the receiving circuit unit 250 nor the transmitting circuit unit 252 operates, The control circuit 282 produces a signal at a first signal level for application to the variable level power supply 216 by the connecting element 240 and the line 228 on line 300. vice versa, Whether the signal supplied to the control circuit 28 2 by the line 228 enables the transmission circuit unit 252 to operate, Or if it indicates that it should be operational, Control circuit 282 produces a signal on line 300 to be the second signal level. Accordingly Power supply 216 produces a signal on line 222 at a power level that depends on the signal level of the signal produced on line 300 by control circuit 282. In the preferred embodiment of operation of the wireless telephone 210, When the transmission circuit unit 252 is not operable, Or if it should not be operational, The first signal level signal generated on line 300 by control circuit 282 causes power supply 216 to generate a power level signal on line 222 that enables recharging of the battery cells of battery power supply 270. When the transmission circuit unit 252 is operating, The control circuit 28 2 generates a signal of the value of the second signal level on the line 300 to enable the power supply 216 to operate the transmission circuit unit 252 (and also the reception circuit unit 250) on the line 222. Signal at a second signal level such that the battery cells of the rechargeable battery power supply 270 are not recharged. In this way, Recharging of the battery cell of the rechargeable battery power source 270 is performed only when the transmission circuit unit 252 is not operating. by this, Overheating of the radiotelephone 210 in response to simultaneous recharging and transmission is avoided. The control signal generated by control circuit 282 on line 294 operates to control the operation of charge regulator 258. If the signal generated by the power supply 216 should be used to provide the charging current to recharge the battery cells of the battery power supply 270, The charge control signal generated on line 294 by control circuit 282 is at a level such that the regulated charge signal generated on line 264 is at a value for such recharging. The exact value of the regulated charge signal is maintained by the feedback control loop. vice versa, If the battery cells of the battery power source 270 should not be recharged (eg, During the time when the transmission circuit unit 252 should be operable), The charge control signal generated by control circuit 282 on line 294 is at a level that prevents the regulated charge signal from being generated on line 264 by charge regulator 258. Therefore, In the preferred embodiment, If the transmitter circuitry 252 of the wireless telephone 210 should operate to transmit a modulated signal, The control circuit 282 generates a signal on line 294 to prevent the regulated charge signal from being applied to the battery cells of the battery power source 270 and also generates a signal on line 300 at the first signal level. And causes power supply 216 to generate a reduced level of signal on line 222 needed to power only receive and transmit circuitry 250 and 252. vice versa, When the transmission circuit unit 252 should not operate, The charge control signal generated on line 294 is of a level such that the regulated charge signal can be provided to the battery cells of battery power source 270. And the second signal level signal is generated on line 300 to cause power supply 216 to generate a power level signal on line 222 that enables recharging of the battery cells of battery power supply 270. (Prevents circuitry within receive and transmit circuitry 250 and 252 from applying power on line 246 to respective circuitry 250 and 252. 3.) Radiotelephone 210 is further shown as including an input element or input element 312 connected to receiving and transmitting circuitry 250 and 252 by line 318. Similarly, Display element or display element 324 is also coupled to circuitry 250 and 252 by line 328. Next, a partial block of FIG. Moving on to the partial schematic, Shown here by the reference numeral 358, The charge regulator is shown. Charge regulator 358 is similar to charge regulator 258 of wireless telephone 210 of FIG. 2 and charge regulator 58 of electronic device 10 of FIG. A charge signal similar to the signal generated by power supplies 216 and 16 in the previous figure is provided by line 446 to charge regulator 358. The charge control signal is provided to charge regulator 358 by line 494 in a manner similar to the charge control signals of charge regulators 58 and 258 of FIGS. 1 and 2 being generated on lines 94 and 294, respectively. Also, A conditioned charge signal is generated on line 464 in a manner similar to the conditioned charge signal generated on lines 64 and 264 of FIGS. 1 and 2, respectively. The signal generated on line 446 is provided to the source electrode of field effect transistor 504. The drain electrode of transistor 504 is coupled to line 464 through resistor 510 and diode 516. Configured to form a differential amplifier, Comparator 524 includes a positive input connected to the left side of resistor 510 via resistor 530. The negative input of comparator 524 is connected to the right side of resistor 510 via resistor 536. For shunt (shunt: Shunt) resistors 542 and 548 further add to comparator 524, Respectively, It is coupled to the positive and negative inputs. Comparator 524 produces a differential output signal on line 554 representing the difference between the signals applied to its positive and negative inputs. Since the signals applied to the positive and negative inputs of comparator 524 represent the voltage levels on the left and right portions of resistor 510, The signal produced on line 554 represents the voltage drop across resistor 510. (Also, Since the voltage is related to the current at the drain electrode, The signal produced on line 554 is related to the current on line 464.) Line 554 is coupled to the positive input of comparator 560. Comparator 560 is also configured to form a differential amplifier. The charge control signal generated on line 494 is applied to the negative input of comparator 560. The differential output of amplifier 560 generated on line 566 is supplied to the gate electrode of transistor 504 via resistor 572. A shunt capacitor 578 is further connected between the gate electrode of the transistor 504 and the ground. The loop formed between the drain electrode of transistor 504 and its gate electrode forms a feedback group, The feedback group causes the value of the signal applied to the drain electrode and the gate electrode of transistor 504 to control the current level of line 464 to cause transistor 504 to operate in a traditional manner (similar to the operation of a vacuum tube). , The current of the signal generated on line 464 (and Therefore, Power level). Also, The value of the charge control signal provided on line 494 controls the value of the signal applied to the gate electrode. Appropriate variation in the value of the signal generated on line 494 causes the signal generated on line 464 to be any desired value. next, Moving to the schematic of FIG. 4, Collectively referred to by reference numeral 610, A wireless phone is shown. The radiotelephone 610 corresponds to the radiotelephone 210 shown in the block diagram of FIG. Elements of the wireless telephone 210 shown in block form in FIG. Except for the rechargeable battery power source 270, shown here as comprising the battery pack 614, It is located within the housing of the wireless telephone 610 of FIG. Radiotelephone 610 is connected to variable level power supply 616 via lines 622 and 628, The lines 622 and 628 connect the power supply 616 to the connecting elements of the radiotelephone 610 via the plug connector 630. (The connection element of the wireless telephone 610 is hidden in the drawing, Corresponding to connecting elements 234 and 240 of FIG. ) A plug connector 636 is also shown in the drawing, The power supply 616 can be connected to a traditional household power supply. (Plug connector 636 consists of a plug connector that allows you to connect to a traditional household power source, of course, Other plug connectors that allow connection to other types of power sources can be used as well. ) The power supply 616 is located remotely from the wireless telephone 610, Connected by lines 622 and 628, Wireless telephone 610 can be suitably operated by a user despite the connection between wireless telephone 610 and power supply 616. If the wireless telephone 610 operates in "standby" mode, The control signal generated by the radiotelephone 610 on line 628 causes the power supply 616 to generate a relatively high power level signal on line 622 to allow recharging of the battery cells of the battery pack 614 comprising a rechargeable power source. To However, If the wireless telephone 610 operates to transmit a modulated signal, Radiotelephone 610 generates a control signal on line 628 to cause power supply 616 to generate a relatively low power level signal, The battery cells of battery pack 614 are not recharged and the signal generated on line 622 is at a power level that enables powering the transmit and receive circuitry of the wireless telephone. In this way, The overheating of the wireless telephone 610 can be avoided, This is because the transmission circuit section of the radio telephone 610 and the battery cell of the battery pack 614 are not recharged at the same time. Next, moving to the flowchart of FIG. 5, Generally referred to by reference numeral 700, which is executable by the control circuitry of the wireless telephone 210 of FIG. The algorithm is shown. When executed, The algorithm 700 uses a battery power source 270 (or Regarding the wireless telephone 610 of FIG. Supply of charging current to the battery pack 614), And again the power supply 216 (or For wireless phone 610, A control signal is generated on lines 294 and 300 to control the power level of the signal generated by power supply 616). At the beginning, As indicated by decision block 760, A determination is made as to whether a variable level power supply is connected to the wireless telephone. If the power source is not connected to a wireless telephone, No branch is taken, And the receiving and transmitting circuitry 250 and 252 of the radiotelephone 210 is powered by the stored energy of the battery power supply 270. However, If the power source is connected to a wireless phone, A yes branch is taken to decision block 718 and a determination is made as to whether transmit circuitry 252 is operable to transmit the modulated signal. If the wireless telephone is in "standby" mode or not and the transmitter circuitry 252 is not operational, No branch is taken, The control signal of the first signal level is As indicated by block 724, Generated on line 300, And the charge control signal generated on line 294 is As indicated by block 730, Charge regulator 258 is generated at a value capable of producing a regulated charge signal on line 264 to recharge the battery cells of battery power supply 270. However, If the transmitting circuit unit 252 is operable or should operate, The yes branch is taken from decision block 718, As indicated by block 736, The control signal generated on line 300 is of a second signal level value, And the charge control signal generated on line 294 is As indicated by block 742, The signal level is such that charge regulator 258 does not generate a regulated charge signal on line 264. Algorithm 700 is repeated during the operation of wireless telephone 210. FIG. Of the preferred embodiment of the present invention, Collectively referred to by reference numeral 800, 3 is a logical flow chart showing the method steps of the method. The method 800 operates to receive operating power of any of at least two power levels generated by a variable level power supply when the variable level power supply is connected to a wireless telephone. Enables power supply to the transmitting / receiving circuit of a wireless telephone At the beginning, And, as indicated by block 806, A variable level power supply is releasably connected to the wireless telephone to provide operating power to the wireless telephone. next, And, as indicated by block 812, A rechargeable power source is coupled to receive the charging signal in response to the variable level power source being coupled to provide the electronic device with a first power level of operating power. next, And, as indicated by block 818, The transceiver circuit is provided with either operating power generated by a variable level power supply or power generated by energy stored by a rechargeable power supply. Finally, And, as indicated by block 824, A power supply control signal is generated for applying to the variable level power supply, The power supply control signal is of at least a first signal level that causes the operating power of the variable level power supply to be a first one of the at least two power levels, Alternatively, it is at a second signal level which causes the operating power of the variable level power supply to be the second of the at least two power levels. An electronic device according to a preferred embodiment of the present invention, And a method therefor allows the power level of an externally generated signal to be a level that depends on the power needs of such electronic devices, Excessive heat generation caused by the application of large amounts of power to the electronic device is avoided. Although the present invention has been described with reference to the preferred embodiments shown in the various drawings, Other similar embodiments can be used to achieve the same function as the invention without departing from it. And it should be understood that modifications and additions can be made to the described embodiments. Therefore, The invention should not be limited to any single embodiment, Rather, it should be construed in breadth and scope in accordance with the recitation of the appended claims.

Claims (1)

[Claims]   1. The power generated by the variable level power source when connected to the variable level power source. An electronic device that is detachably connectable to the variable level power supply to receive power. hand,   A connector that can be connected to the variable level power supply, wherein the connector is A first connecting element for receiving the power generated by the variable level power supply A second connection element for providing a power control signal to the variable level power supply. Including the   Powered from the variable level power supply is operably coupled to the first connecting element. Rechargeable power source receiving power, and   Operably coupled to the rechargeable power source and the second connecting element An electronic circuit that provides a power supply control signal indicating an operation mode of the electronic circuit,   An electronic device comprising:   2. The rechargeable power source is a battery power source that includes at least one battery cell. The electronic device of claim 1, comprising a source.   3. The electronic circuit is connected to the variable level power supply at the first connection element. Electricity thus generated and energy stored by said rechargeable power source Operatively coupled to alternately receive any of the power generated by The electronic device of claim 1, which is configured to:   4. The electrical circuit of claim 3, wherein the electrical circuit comprises at least a portion of a wireless transceiver. Electronic device.   5. The electronic device of claim 4, wherein the wireless transceiver comprises a wireless telephone.   6. Furthermore, the first connecting element of the connector and the rechargeable battery are A source for operably coupled to receive power from the variable level power source and Adjusting the current of the power from the variable level power supply to recharge the rechargeable power supply. 7. A charge regulator for producing a regulated charge signal for: Electronic device as described.   7. Is the charge regulator operatively coupled to receive a charge regulation signal? Comparing a signal indicative of the current of the adjusted charging signal with the charging adjustment signal; The power supply according to claim 6, further comprising a feedback control circuit for adjusting a current of the power. Child device.   8. Into the electronic circuit using the power generated by the connected variable level power supply A method of recharging an associated rechargeable power source, comprising:       (A) receiving power generated by the variable level power supply and such Supplying power to the rechargeable power source to recharge the rechargeable power source , And       (B) A power supply indicating an operating mode of an electronic circuit associated with the rechargeable power supply Providing a control signal to the variable level power supply Stage of offering,   A method of recharging a rechargeable power source associated with an electronic circuit comprising.   9. The electronic circuit is provided by a wireless transceiver with an associated rechargeable power source. 9. The method of claim 8 provided. 10. further,       (C) Adjustable current of electric power from the variable level power source and rechargeable Generating a regulated charging signal for the recharging of different power sources,   9. The method of claim 8, comprising: