KR0137446B1 - Method of power reduction a pager - Google Patents

Abstract

The present invention is a method of turning on / off the power supplied to the high frequency receiver by the demodulation control signal after the power of the pager is turned on. Only the N bits specified in the preamble signal, synchronization signal, and address code signal detection routine of the received paging signal are used. In comparison, if the signal coincides with a prescribed code signal or address signal, it compares continuously and if it does not match, it is determined as a detection error, and a power saving method of the pager is provided to immediately turn off the power supplied to the high frequency receiver.

Description

Power saving method of pager

1 is a block diagram showing an example of the configuration of a conventional pager.

2 is a flowchart illustrating a signal detection method of a conventional pager.

3 is a diagram showing the code format of a POCSAG signal used in a general pager.

4 is a diagram showing the configuration of a synchronization code in a POCSAG signal.

5 is a diagram showing the structure of an address word signal in a POCSAG signal.

6 is a diagram showing a power supply timing from a conventional pager to a high frequency receiver.

7 is a flow chart illustrating a method of the present invention.

8 is a power supply timing diagram according to the power saving method of the present invention.

The present invention relates to a power saving method for minimizing battery power consumption of a pager.

The conventional pager has a microprocessor 30 for controlling each part of the pager, a high frequency receiver 10 for receiving a paging signal, and a POCSAG signal received by the receiver, as shown in FIG. A demodulator 20 for restoring the data to the microprocessor 30, a memory unit 50 for storing the detected code signal and address information, and a message received under the control of the microprocessor 30. The LCD display unit 60, and a power supply unit 40 for boosting to a proper voltage using the built-in battery and then supplied to each circuit.

Such a pager is operated to supply power to the high frequency receiver 10 in connection with a signal detection operation of the demodulator 20 for demodulating the POCSAG signal received by the high frequency receiver 10 through an antenna. As described above, the operation of controlling the power supplied to the high frequency receiver 10 by the demodulator 20 will be described in detail with reference to the flowchart of FIG. 2. It is checked whether a preamble portion of the received POCSAG signal is detected, and power is supplied to the high frequency reception number 10 until the preamble signal is detected. In step 110, if the preamble signal is detected, go to step 120 and check whether the sync code signal is detected and supply power to the high frequency receiver 10 again until it is detected, and then until it is detected in the address signal detection process of step 130, By continuously supplying power, the user can receive a message signal after the detection operation is completed.

Here, referring to FIG. 3, the code format of the POCSAG signal received by the radio call receiver is located in the preamble signal portion having an 18 word size in front of the code signal. Batch signals in word units follow the series according to the amount of information.

As shown in the figure, one batch signal is composed of eight frames consisting of one word (32 bit) size synchronization signal (SY) and two words, and each word includes an address signal, a message signal, and an idle signal. do.

In addition, since the preamble signal is composed of 18 words in 32-bit units in which one signal and zero signal are alternately formed, the preamble signal has a total size of 576 bits, and thus a time for detecting the preamble signal is relatively long.

Further, as shown in FIG. 4, the synchronization signal has a size of 32 bits in the form of a unique code, and the address word signal subsequent thereto is a 1-bit flag and an 18-bit address bit as shown in FIG. It consists of two bits of tone select bits, ten bits of check bits, and one bit of parity bits.

As shown in FIG. 6, the power supply to the high frequency receiver 10 in the pager as described above is powered by the preamble signal detection section, the synchronization signal (SY) detection section, and the frame signal, that is, the address and message word detection section. There is a problem that the power supply continues to be turned on, and furthermore, even when an error occurs in the detection signal during the detection period of the signal due to the noise or the like upon reception of the radio call signal. Accordingly, there is a disadvantage in that the battery life is shortened because the current consumption of the pager using a single 1.5V battery is large.

Accordingly, the present invention is to solve the problems of the prior art as described above, the preamble of the received paging signal by a method of turning on / off the power supplied to the high frequency receiver by the control signal of the demodulator after the power of the radio pager is turned on. The signal, sync signal, and address code signal detection routine compares only N bits specified in advance and if the signal matches the specified code signal or address signal, compares it continuously. It provides a power saving method of a wireless pager.

Hereinafter, the method of the present invention will be described in detail with reference to the accompanying drawings.

First, the hardware configuration for performing the method of the present invention is the same as that of the conventional apparatus shown in FIG. 1, and the system is used as a method for controlling the power supply ON / OFF to the high frequency receiver 10 by the decoder which is the local demodulator 20. The controlling microprocessor 30 is used to perform the power saving method of the present invention as shown in the flowchart of FIG.

In FIG. 7, after turning on the power switch of the pager in step 200, a detection routine of whether the preamble portion of the above described POCSAG signal is received in step 210 is performed to supply power to the high frequency receiver 10 in step 220. Then, the predetermined N bits are compared with the preamble signal code values stored in the memory unit 50.

If the first N bits compared match the prescribed preamble signal code, the process proceeds to step 240 and power supply to the high frequency receiver 10 is continued until the detection of the remaining preamble signals is completed.

If the first compared N bits do not match the prescribed code value, the power supplied to the high frequency receiver 10 is turned off in step 230.

When the preamble signal detection step is completed, the flow advances to step 250 to start a synchronization signal detection routine to continue supplying power to the high frequency receiver 10 and to compare whether the minimum N bits of the synchronization signal match the prescribed code value (step 260). ). As in the preamble signal detection step, if the N bits of the received synchronization signal match the prescribed synchronization code, power is continuously supplied until the remaining synchronization signal detection is completed, and if the compared code value is out of the specified value, the process goes to step 270 and the high frequency receiving unit Cut off the power supplied to (10).

Once the synchronization signal detection step is completed, the address signal detection routine is started in step 280. In step 290, power supply to the high frequency receiver 10 is continued to check whether the received first N-bit address code signal matches that of the user-specific address code stored in the memory 50. If the address codes coincide with each other, the remaining address codes are continuously compared with each other. When the address codes are different from each other, the power supply supplied to the high frequency receiver 10 is turned off.

When the detection of this address code signal is completed, the detection operation of the subsequent message word is performed.

As described above, in the method of reducing power of the wireless paging receiver according to the present invention, as shown in FIG. 8, the on / off timing of the power supplied to the high frequency receiver in the preamble signal detection process is shortened to an initial N bit among 32 bits. This saves the power required for the initial detection, and cuts off the power supply immediately when a detection error that differs from the code value specified by external interference or noise occurs during synchronization code signal or address code signal detection. This can bring about the desired battery power savings.

Claims (1)

Comparing the first predetermined N bits with the code value of the prescribed preamble signal when the preamble signal of the paging signal is received; and when the detection of the preamble signal is completed, the predetermined first N bits of the subsequent synchronization signals are defined. Comparing the signal code value with each other, and comparing the first predetermined N bits of a subsequent address code signal with a user-specific address code value when the synchronization signal detection is completed, and comparing the preamble signal, the synchronization signal, or the like. In the process of detecting the address signal, when each of the first N bits compared does not coincide with each of the prescribed code values, the power supplied to the high frequency receiver inside the receiver is turned off. Detection of bits other than the N bits when the code value of Power saving method of a radio pager, comprising a step of constantly maintaining the power supplied to the high-frequency receiving unit to sokdoel.