FR2683408A1 - METHOD FOR SAVING THE ENERGY OF THE BATTERY OF A WIRELESS TELECOMMUNICATIONS DEVICE, AND TELEPHONE APPARATUS, PARTICULARLY OF THE CORDLESS TYPE, USING THE SAME. - Google Patents

Abstract

The process of the present invention conserves battery power for a cordless telephone, comprising a base unit and a remote unit. The remote unit has a receiver (205), keypad (222) and a battery saver switch (601) for enabling a power conservation mode or a normal mode. The process consists of first determining which mode the battery saver switch (601) is enabling. If the normal mode is enabled, power is periodically applied to the receiver (205) and the keypad (222) is scanned for a depressed key. If the power conservation mode is enabled, the keypad (222) is scanned periodically for a depressed key while the receiver (205) remains in an unpowered state.

Description

 The present invention relates generally to the field of telecommunications and, in particular, cordless or cordless telephones. It relates more specifically to a method for saving the energy of the battery of such a telephone, as well as to a telephone apparatus using this method.

Cordless phones are typically home use units, which include a base unit and one or more units that operate remotely. We can see an example
o of such a cordless telephone in US Pat. No. 4,989,230 to Giltig et al., which has been assigned to the company Motorola Inc. The units intended to operate remotely communicate with the base unit by radio means ( radio frequencies, or RF) over a typical range of 300 m from the base unit. The base unit is connected to the landline telephone system, which allows a remote user to communicate with other telephones in the landline system.

The unit operating remotely, to save energy, leaves the receiver in the power off state, applying the voltage periodically for a short time. The receiver is switched on to check whether there is a key pressed on the keyboard or an incoming call signal coming from the base unit, since the unit operating remotely has a warning transducer. call used to announce an incoming call. When the receiver has been switched on, it consumes a large amount of energy in the battery of the remote operating unit, which reduces the time during which
The remote operating unit can be used for a telephone call. There is therefore a need for a means of reducing the energy used by the unit operating remotely when it is not used for a telephone call.

The method according to the invention saves the energy of the battery of a wireless telecommunications device. This device has a reception means, a data input means, and a battery saver switch used to validate an energy saving mode or a normal mode. The method is to first determine which mode the battery saver switch is
valid territory. If the normal mode is enabled, the voltage is periodically applied to the reception means and the data entry means is scanned to find a key pressed. If the mode
energy saving is validated, the data input means is periodically scanned for a key pressed while the receiving means remains in the power off state.

The following description, intended as an illustration of
the invention aims to give a better understanding of its
features and benefits; it is based on the appended drawings, among which
Figure 1 shows the block diagram of the base unit of a cordless phone;
Figure 2 shows the block diagram of the unit operating remotely from a cordless telephone;
Figure 3 is a flow diagram of the process for validating a demonstration, or test, interference mode;
Figure 4 shows the block diagram of a draft
their in integrated circuit form;
Figure 5 is a flow diagram of the energy saving method according to the invention; and
FIG. 6 represents the functional diagram of a battery saving circuit according to the invention.

 The method according to the invention makes it possible to reduce the time during which energy is used by the receiver of the unit operating remotely. When a switch has been placed in the position corresponding to the energy saving mode, the receiver is not periodically energized as in the normal mode, which makes it possible to reduce the energy consumption.

 The block diagram of Figure 1 shows a preferred embodiment of a cordless telephone base unit having an adjustable scrambling or encryption circuit for encrypting and decrypting signals. This particular base unit also includes a microphone and speaker unit.

Figure 2 shows a preferred embodiment of a remote operating unit which is intended to communicate with the base unit, the remote operating unit also having an adjustable scrambling or encryption circuit for encryption and decipher signals.

 As can be seen in Figure 1, the base unit includes an antenna 101 which is connected to the transmit and receive paths of the base unit. The reception path includes a bandpass filter 102 which allows the frequencies from 49.670 to 49.990 MHz to pass. The filter is connected to a reception amplifier 103 which amplifies the filtered signal by approximately 18 dB. The amplifier output signal is then filtered by another bandpass filter 104 before being applied to the input of the receiver 105. In the preferred embodiment, the receiver is a model MC3363 from the company Motorola Inc .

Receiver 105 lowers the signal to 10.7 MHz, then to 455 kHz. Then this signal is subjected to demodulation. The local oscillators contained in the receiver 105 are controlled by a phase control loop 120 whose frequency is controlled by a microprocessor 112. The microprocessor 112 also receives a carrier detection signal and the signal to be demodulated, called RX data, from the receiver 105. The demodulated signal is used by the microprocessor 112 to interpret the coded data messages transmitted by the unit operating remotely. These coded data messages are used for dialing a DTMF number (multifrequency in code 2), controlling the telephone hook switch and controlling the jamming circuit. The carrier detection signal is used to detect presence a transmitter occupying the reception channel of the base unit. In the preferred embodiment, the microprocessor 112 is a model MC68HCL05C4 from the company Motorola
Inc.

 The output signal from the receiver 105 is again filtered by another bandpass filter, 106. The output signal from the filter 106 is applied to the input of a scrambling circuit 107.

In the preferred embodiment, the scrambling circuit 107 is a scrambler for a duplex voice band in the form of the integrated circuit MX108DW, from the company MW. Com, Inc.

the descrambled output signal from the interfering circuit 107 is filtered by a de-emphasis filter 108 before being applied to the input of an expander 109. The expansion operation applies a gain which varies according to the input signal of
The amplitude of the signal, the effective gain being greater for the signals of large amplitude and lower for the signals of small amplitude. After this signal has been filtered by a high-pass filter 110, it is applied to the input of a circuit forming a microphone and speaker block 111 and is also supplied to the land line telephone system. If the microphone and speaker unit is in use, for example for triple communication between the base unit, the remote unit and the land line side, the audio signal is output to the speaker. the basic unit.

 The transmission path of the base unit consists of the audio signal, coming either from the microphone 121 of the microphone and speaker block, or from the land line side, which has been subjected to bandpass filtering 113 before passing in a compressor 114.

The compressor 114 applies a gain to the audio signal which varies according to the amplitude of the signal, the effective gain being greater for the small signals. An example of a compander (compressor-expander) is the model MC33110 manufactured by the company
Motorola Inc. The dynamic range of the compander is 80 dB.

The output signal of the compressor 114 is applied to the input of a pre-emphasis filter 115 before being scrambled by the interfering circuit 116. The interfering circuit 116 is formed by the second part of this same integrated circuit which is used for descramble the received signal. The scrambled audio signal is subjected to bandpass filtering 117 before being modulated by the transmitter 118 at a frequency in the range of 46.610 to 46.970 MHz. The frequency actually used by the telephone can be adjusted by the user by means of a switch or other control means placed on the base unit or the unit operating remotely from the telephone. Both the receive and transmit frequency ranges are set by the FCC (Federal
Communications Commision) for all cordless phones. An example of a transmitter is MC2833, manufactured by the company
Motorola Inc.

 The output signal from the transmitter is filtered by a bandpass filter 119 used to rid the signal of frequencies outside the range 46.610-46.970 MHz. The signal is then transmitted by the antenna 101 to the unit operating remotely.

 The remote operating unit consists of an antenna 201 which receives the signal from the base unit. A bandpass filter 202 removes the portion of the signal that is outside of the range 46.610-46.970 MHz. A gain of approximately 18 dB is then applied to the signal by a reception amplifier 203 before it is again filtered by a bandpass filter 204. This signal is then applied to the input of the receiver 205, which includes, as usual, and as the receiver 105 of the base unit, a local oscillator, mixers, crystal filters and a detector.

 The remote control unit's receiver 205 lowers the signal to 10.7 MHz, then 455 kHz. This signal is then demodulated. The demodulated signal, called RX data, is applied to the input of microprocessor 212 to allow the interpretation of coded data messages sent by the base unit. These coded data messages are used to control the calling device of the remote operating unit and the jamming circuit.

 The demodulated signal is also filtered by a bandpass filter 206 before being applied to the input of the interfering circuit 207 performing a descrambling operation. The jammer circuit 207 is identical to the integrated circuit used in the base unit.

 The descrambled output signal is filtered by a de-emphasis filter 208 before passing through an expander 209. The expanded signal is filtered by a bandpass filter 210 and is amplified by an amplifier 211. The amplifier 211 is controlled by the microprocessor 212. By actuating a command on the unit operating remotely, the user can increase or decrease the volume of the speaker 220 by increasing or decreasing the gain applied to the signal at this point.

The amplified signal is then applied to the input of the speaker of the earpiece of the remote operating unit.

 The microphone 221 of the remote operating unit produces the audio signal which is filtered by a bandpass filter 213, is compressed by a compressor 214 and is filtered by a pre-emphasis filter 215 before being processed by the interfering circuit 216 This circuit 216 is formed of the second part of the integrated circuit used to descramble the received signal.

 The scrambled signal is filtered by a band-pass filter 217 before being modulated at a frequency belonging to the interval from 49.67 to 49.99 MHz by the transmitter 218. The modulated signal is filtered by a pass-filter band 219 so that the signals outside this frequency interval are suppressed, and it is transmitted on the antenna 201 of the device operating remotely.

The keypad on the remote operating unit 222 is used to "pick up" the phone, enter phone numbers, change the frequency used to communicate with
The base unit and to validate the jamming demonstration function. The keyboard validates the demonstration, or test, jamming function by instructing the microprocessor to produce a control signal intended for the integrated jamming circuit. In the preferred embodiment, the base unit also has a keyboard.

 The control signals used in the two units, remote and basic, are applied to the transmitter after the scrambling function, so that these signals are not scrambled. The control signals produced by the microprocessor are the subject of a logical meeting (OR wired) with the scrambled voice signal before delivery to input from the transmitter.

 Signal jamming between the remote unit and the base unit takes place continuously. However, this interference does not appear to the telephone user or the recipient of the call. We therefore cannot know whether the interference is operating correctly. The jamming demonstration process according to the invention offers the two people participating in the telephone call the possibility of hearing the scrambled version of the signal.

 The jamming demonstration process is illustrated in Figure 3. During a phone call, the keyboard is scanned (step 301) by the microprocessor so that it is searched for if a key has been pressed, for example a Demo Security key, indicating the user of the remote unit wishes to enter the interference demonstration mode. In the preferred embodiment, this mode is called the Demo Security mode.

 If the key has been pressed (step 302), a timer arranged in the microprocessor is put into operation (step 303).

If the key is released immediately (step 304), the timer is cleared (step 305) and the keyboard scanning resumes (step 301).

If the key is still held (step 304), the timer will increment (step 306) and a check will be made to determine if the key has been pressed for at least 3 seconds
(step 307). This time check continues until
the button has been pressed for 3 seconds. At this time, the jamming demonstration mode comes into play (step 308). This can be indicated on the remote operating unit or the base unit by a flashing indicator light (309). The keypad of the remote operating unit can be used for the above operation or, if the base unit has a keypad, this keypad can be used to enter the jamming demonstration mode.

 The block diagram of the duplex voice band jammer "MX108DW" is illustrated in Figure 4.

Since this integrated circuit uses frequency inversion interference, an already scrambled signal which is applied to the input of the circuit will be brought back to the normal form by the circuit.

 To be able to put the phone into the jamming demonstration mode, the integrated circuit MX108DW must be able to transmit the input signal without jamming. This is achieved by applying the "clear / scrambled" command (CLR / SC). By applying a logic level 1 to this input, the signal will be transmitted on the path by the "clear" channel. The application of a logic level 0 to this control input will cause the signal to be transmitted on the path by the "scrambled" channel.

 The preferred embodiment of the cordless telephone disables the entire jamming integrated circuit, which is located in the remote unit, when the jamming demonstration mode has started. This allows the scrambled audio signal to be heard both by the telephone user and their correspondent on the land line side.

 The energy saving process according to the invention, which is illustrated in Figure 5, begins while the microprocessor is in a shutdown or sleep mode (step 501). The microprocessor then receives an interrupt (step 502) from an external clock pulse. This interruption is carried out periodically to allow the microprocessor to check whether there are input signals from the base unit or from the keyboard of the unit operating remotely.

 The microprocessor then checks the battery saver switch to determine which mode the phone is in (step 503). If the switch is in the normal operating mode, the voltage is applied to the receiver and the received signals are checked to indicate whether it is data from the base unit (step 504). If the battery saver switch is in the power save mode position, voltage is not applied to the receiver.

 A keyboard scan was performed to determine if a key was pressed (step 505). If a key has been pressed (step 506), the instruction associated with this key is processed (step 507). For example, this key can be the repeat key for the last number dialed or a dial key for dialing a telephone number.

 If no key has been pressed (step 506), it is determined whether voltage has been applied to the receiver (step 508).

If the receiver is on, it is determined whether data has been received (step 509). If data has been received, this data is processed (step 510). An example of data received consists of a call signal from the base unit and instructing the remote unit to activate the ringing tone. Software means operating as a timer is then checked to determine whether the microprocessor has been active for the desired time (step 511). In the preferred embodiment, the microprocessor is awake (i.e. not in the shutdown or sleep mode) for 40 ms in the power saving mode and for 125 ms in the normal mode. The shortened time which is associated with the energy saving mode reduces the energy charge imposed on the battery of the unit operating remotely.

 If the time has not elapsed (step 511), the process is repeated from the scanning of the keyboard (step 505). If the time has elapsed (step 511), the application of the voltage to the receiver is suppressed (step 512), if it had been applied initially.

 If the battery saver switch is in the power save mode (step 513), the time is reset to 40 ms (step 515). If the switch is in normal mode, the time is repositioned on 125 ms (step 514). The microprocessor then returns to the sleep state for 1.2 seconds, in the preferred embodiment, after which the process begins again.

The battery saving circuit according to the invention is illustrated in FIG. 6. This circuit consists of a switch 601 connected to the input of the microprocessor 602. When the switch 601 is closed, a logic level 1 is applied to the input microprocessor 602, which indicates that the phone is in power saving mode. The interrupt designed to extract the microprocessor 602 from the sleep mode comes either from the keyboard 603 or from the sleep timer 604. A transistor switch 605 is connected to the microprocessor in order to allow the latter to make the transistor 605 conductive and d '' apply voltage to the receiver. The collected data that is received from
the base unit is applied by the receiver to the microprocessor.

As long as it is in energy saving mode,
the cordless telephone can also establish or receive calls by pressing a key on the keyboard or, in the preferred embodiment, by opening the protective flap of the unit operating remotely. Once the call has ended, the unit operating remotely automatically returns to the energy saving mode, if it was the mode selected before the call.

 In addition, in the preferred embodiment, the user can use the remotely operated device to enter telephone numbers and store them in the memory of the base unit for subsequent calls from the memory. . These numbers can be entered while the unit operating remotely is in the energy saving mode. In this case, the microprocessor automatically powers on the transmitter and sends the numbers to the base unit so that they are stored there. After a certain time, the transmitter goes into the power off state and the remote operating unit automatically returns to the energy saving mode if it was the previously selected mode.

 In summary, a cordless telephone which has adjustable jamming means between the remotely operating unit and the base unit has been presented, which provides the desired security for conversations between the telephone user and a party located in the land lines side. The phone also has a mode for normal power consumption and a power saving mode. When the phone has been placed in the power saving mode, it can be used longer between two charges of the battery.

 Of course, those skilled in the art will be able to imagine, from the device or the method in the description has just been given by way of illustration only and in no way limitative, various variants and modifications not departing from the scope of the invention.

Claims (6)

 1. Method for saving bat energy  included in a wireless telecommunications device having receiving means, data input means, and a battery saver switch for enabling an energy saving mode or a normal mode, the method being characterized by the following operations  determine which mode the battery saver switch is enabling;  if the normal mode is validated, apply periodically  the voltage at the receiving means;  if the normal mode is validated, scan the data input means to find the existence of a key pressed when the voltage is applied to the reception means; and the method being further characterized by the following operation  if the energy saving mode is enabled, periodically scan the data input means to check for the existence of a key pressed at the same time as the reception means remains in the de-energized state.  2. Method according to claim 1 further characterized by the following operations:  if the normal mode is validated, check the existence of data after the voltage has been applied to the reception means; and  suppress voltage application by means of reception  3. Method for saving battery power in a wireless telecommunication device having reception means, data input means, and a battery saver switch for validating a saving mode of energy and a normal mode, the process being characterized by the following operations:  determine which mode the battery saver switch is enabling;  if the normal mode is validated, periodically apply the voltage to the receiving means;  if the normal mode is validated, scan the data entry means to search for the existence of a key pressed when the power is applied to the reception means;  if the energy saving mode is validated, periodically scan the data input means to search for the existence of a key pressed without applying the voltage to the reception means;  if the normal mode is validated, check the existence of data after the power has been applied to the reception means; the method being further characterized by the following operation  if the voltage has been applied to the receiving means, withdraw the voltage application to the receiving means.  4. Method for saving battery power in a cordless telephone having a base unit and a unit operating remotely, the base unit transmitting data signals to the unit operating remotely on a telecommunication channel, the unit operating remotely having a reception means, a data entry means which has several keys, a processing means, and a battery saver switch used to validate a normal mode or a energy saving mode, the process being characterized by the following operations:  a) periodically interrupt the processing means;  b) if the normal mode is validated when the processing means is interrupted, apply the voltage to the receiving means;  c) if the energy saving mode is validated when the processing means is interrupted, keep the receiving means in the de-energized state;  d) scanning the data entry means to search for the existence of a key pressed;  e) if a key has been pressed, process the instruction associated with the key;  f) if the voltage has been applied to the receiving means, check for the existence of data signals transmitted by the base unit;  g) repeating the operations from operation d) for a first predetermined duration if the normal mode is validated and for a second predetermined duration if the energy saving mode is validated; the method being further characterized by the following operation  h) if the voltage has been applied to the receiving means, withdraw the voltage application to the receiving means.  5. Method according to claim 4, characterized in that the first predetermined duration is 125 ms and the second predetermined duration is 40 ms.  6. A cordless telephone apparatus having a remote operating unit (201 to 222) and a base unit (101 to 122) connected to a telephone system, the remote operating unit communicating with the basic unit over a communication path. telecommunications, the unit operating remotely having a receiver (205), a keyboard (222) and a processing means, the apparatus being characterized by  voltage application switching means, connected to the processing means, for controlling the voltage application to the receiver;  a mode switching means, connected to the processing means, and serving to validate an energy saving mode or else a normal mode; the apparatus being further characterized in that  the processing means controls the application of voltage to the receiver in response to the mode switching means and an energy saving method, which comprises the following operations:  determining which mode the mode switching means is validating;  if the normal mode is validated, periodically apply the voltage to the receiver;  if the normal mode is validated, scan the keyboard to find the existence of a key pressed when the voltage is applied to the receiver; the method further comprising the following operation  if the energy saving mode is enabled, periodically scan the keyboard to find the existence of a key pressed while the receiver remains in the power-off state.