KR0149380B1 - Power saving control method of a pager - Google Patents

Abstract

According to the present invention, in the operation of a radio call receiver (pager terminal), the first sync codeword received skips the next and next sync parts and the frame analyzes the data to acquire the data. The present invention relates to a power saving control method of a pager that enables power saving by operating.

With the diversification and miniaturization of the pager design, the battery used in the pager has also been miniaturized, and the miniaturization of the battery has resulted in a shorter pager time.

This shortening of pager use time is very inconvenient because it requires frequent battery replacement from the user's point of view.

Accordingly, the present invention provides a method for determining whether a first sync code word (SY) subsequent to a preamble (PR) is matched, and if it is determined as a result of the determination of the step, ON only in a corresponding frame of subscribers in every subsequent batch. As a method for saving power of a pager, the present invention uses a prescribed POGSAG algorithm, wherein the SY position of the remaining batch is controlled by skipping. It provides a power saving technique that allows the reception capability to remain the same while minimizing current consumption.

Description

Wireless Call Receiver (Pager) Controls Power Saving Operation

1 is a structural diagram of a POCSAG signal which is a general radio call signal.

2 is a timing diagram of a reception control operation of a conventional radio receiver.

3 is a block diagram of a hardware related to a reception of a typical paging receiver.

4 is a timing diagram of a reception control operation according to an embodiment of the present invention.

5 is a flowchart illustrating a power saving exercise control method according to an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: high frequency receiving circuit 2: decoder

3: alarm and liquid crystal display circuit 4: CPU (central controller)

The present invention relates to a reception control method of a wireless paging receiver (page terminal), wherein after the first sync code is detected, the sync code after the first sync code is detected every other time or every other time rather than every sync code. (ACTIVE) The present invention relates to a power saving operation control method that can extend the life of a battery by reducing the time.

In general, a wireless call system transmits data using the POCSAG protocol. The data format structure formatted and transmitted according to the POCSAG protocol is shown in FIG.

As shown in the figure, the unit block of the POCSAG signal is composed of a preamble region PR in which data '1' and '0' are repeated, and a plurality of batch (N BATCH) regions following the preamble region. Each arrangement area internally includes a sync code area SY and eight frame areas F0 to F7, each frame area being copied into two code word areas, and these code words are address information. I carry either message information or one of the IDLEs.

The preamble region has a size of 576 bits, and each arrangement has a size of 544 bits. The sync code area in each batch consists of 32 bits, each of the eight frames has a size of 64 bits, and two codewords in the frame each have a size of 32 bits.

Referring to FIG. 2 and FIG. 3, a data reception operation of a conventional pager (PAGER) for receiving transmission data according to the POCSAG protocol is as follows.

FIG. 2 is a hardware configuration diagram of a general radio calling terminal including a radio calling terminal to which the present invention is applied, and FIG. 3 is a signal reception operation timing of a general radio calling terminal having a hardware configuration of FIG. (A) is a structure diagram of the POCSAG signal stream, and (b) is a signal reception operation timing diagram.

Referring to the operation of the radio call terminal in relation to the signal reception, the high frequency receiving circuit 1 tunes a signal stream as shown in FIG. 1 transmitted over the air at the system side and transmits the same to the device. The CPU 4 checks that preamble detection is performed among the high frequency signals, and in this case, the decoder 2, which is a data analysis circuit, is maintained in an inactive state.

When the preamble area is detected while the CPU 4 examines the received high frequency signal, the decoder 2 is activated (ON), and the first sync code SY following the activated decoder 2 preamble area is detected. . The decoder is then deactivated (OFF). Recognizing that the sync code has been detected, the CPU 4 knows, by presetting, the frame number of the owning subscriber among eight frame areas F0 to F7, and thus, when the frame area is received. Deactivates the decoder 2 again at, and the activated decoder 2 detects an address in the corresponding frame, compares its own address, and informs the CPU 4 if the addresses match, followed by a message. Area information is saved and deactivated. The stored message information is read by the CPU 4 and is displayed and displayed via the high contrast and liquid crystal display circuit 3. Of course, if the address does not match, it tells the CPU that it does not match and is disabled. At the time when the next sync code SY is input, the CPU 4 activates (ON) the decoder 2 again and repeats the above process.

As described above, in the conventional signal reception control operation of the conventional wireless paging terminal, the decoder 2 is continuously activated in the synchronization signal area and the subscriber frame area of each arrangement.

However, in recent years, it has become a trend to miniaturize the wireless paging receiver body and the battery, and a power saving control technique for maximizing battery life is required, while the conventional wireless paging receiver reception control technique as described above is designed to detect a synchronization area in every arrangement. There is a problem that the life of the battery is shortened by converting the decoder 2.

In other words, when the synchronization signal of the first batch is detected, the time until the next subscriber frame area is input is calculated by the CPU to activate the decoder 2, so how many seconds after the second or third batch is the subscriber frame area? If the CPU 4 calculates this time and activates the decoder, there is no problem in receiving information in the subscriber frame area. Therefore, data reception can be normally performed without having to activate the decoder 2 for every sync for detecting the sync code, thereby extending the battery life of the conventional method of detecting every sync code. The problem is that the decoder is activated for synchronous detection of each batch, which shortens the lifetime of the spits.

Accordingly, the present invention has been made to solve the above problems, and after detecting the sync area of the first batch, the decoder is not activated to detect the sync code of the second batch or the sync code of the second and third batches. The purpose of the present invention is to provide a method for controlling power saving operation of a wireless paging receiver that can extend the life of a battery.

In order to achieve the above object, the present invention provides a method of detecting a sync code by activating a decoder in a sync code area of a batch specified in a unit block of one radio call signal stream. Subsequent one or two batches do not activate the decoder to detect the sync code, but activate the decoder to detect the sync code in the next batch.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIG. 4.

4 is a timing diagram related to data reception of a wireless paging receiver according to a power saving operation control method of the present invention, (a) shows a structure of a POCSAG signal stream, and (b) shows a signal receiving operation according to an embodiment of the present invention. The timing diagram is shown.

As shown in the figure, in the data receiving operation according to the embodiment of the present invention, if the POCSAG signal unit block detects the first sync code, the decoder (2 in FIG. 4th sync code is activated by detecting the decoder (2 in FIG. 2), i.e., if a sync code is detected in one batch, the sync code is not detected for the two batches after it. will be. The reception control function as described above is performed to the program executed in the CPU, and the processing procedure of the power saving operation control method according to the present invention will be described with reference to FIG.

5 is a flowchart illustrating a method for controlling power saving operation of a wireless paging receiver according to an embodiment of the present invention.

When battery power is applied and the radio call receiver starts to operate, the CPU (4 in FIG. 2) initializes various variables and checks whether a high frequency POCSAG signal is received and a preamble is detected (10, 11). When the preamble is detected, the decoder (2 in FIG. 2) is activated to check whether a synchronization signal is detected (12, 13), and when the synchronization signal is detected, the decoder is deactivated and a timer is driven to check whether the first predetermined time has elapsed ( 14, 15). In this case, the first predetermined time is a time from the synchronization signal region to the subscriber frame region set in advance in one arrangement.

When the first predetermined time has elapsed, the decoder is activated (16), and the first batch reads the subscriber frame and checks whether the addresses match (17). If the address matches, it means that there is a message sent to it, so the next message is saved, and the decoder is deactivated. If the address does not match, the decoder is deactivated (18).

Then, the timer is restarted to check whether the second predetermined time 20 has elapsed (20), where the second predetermined time is the time from the subscriber frame area of the first batch to the subscriber frame area of the third batch. That is, the synchronization areas of the second and third arrangements are deactivated and skipped.

When the second predetermined time 20 elapses, the decoder is activated to read the subscriber frame area of the third batch, so that if the addresses match, the message is stored and the decoder is deactivated. Inactivate (21-24).

Then, the timer is driven to check whether the third predetermined time elapses, wherein the third predetermined time is the time from the subscriber frame area of the third batch to the sync code area of the fourth batch.

When the third predetermined time has elapsed, the decoder is activated to transition to step 13 in which the synchronization signal is detected to detect whether a synchronization signal is detected.

Therefore, according to the present invention, reception control is performed as shown in FIG. 4B, whereby the battery life is longer than that of the conventional control method (FIG. 3B).

In the present invention, if the idle time and the preamble time existing between one unit block (N batch) of the POCSAG signal are shorter than the time interval between the two batches, there is a risk of operational error. That is, it is the turn to detect the sync code in the last batch, and after the frame of the last batch, the rest period and the preamble of the next block come. Then, any point of the block is detected, and if that happens, the synchronous detection is not performed and the process moves to the step of finding the preamble (11 to 13 in FIG. 5).

Therefore, in the case of the present invention, an operation error does not occur when the sum of the interblock block duration and the preamble time of the POCSAG stream is longer than at least two batch intervals, and the present invention satisfies this.

Usually, the pause time between unit blocks of the POCSAG stream is 1.5 seconds or more. Since the preamble is 576 bits, the time is 1/512 × 576 = 1.125 seconds when the system transmits at 512bps, and when it is transmitted at 1200bps, the transmission time is 1/1200 × 576 = 2.625 seconds or more and 1200bps. Is more than 1,980 seconds.

However, since the two batches are 544 bits and are 2.125 seconds when transmitted at 512bps and 0.9067 seconds when transmitted at 1200bps, the two batch intervals are shorter than the idle time + preamble time so that no operation error occurs.

In addition, the above-described embodiment describes a case of filtering out two batches of sync codes without detecting them. However, the case of filtering out a batch of sync codes without detecting sync codes of one batch has the same technical idea as the present invention. Of course I will.

Accordingly, the present invention is an effective invention that can perform reception control of a radio receiver while saving battery compared to the conventional radio receiver control method of activating a decoder to detect sync codes in every batch.

Claims (1)

A method applied to a radio call receiver to control a reception operation, comprising: activating a decoder to detect a synchronization code in a sync code region of a batch designated in a unit block of one radio call signal stream; Activating the decoder to detect the sync code in the next batch without activating the decoder to detect the sync code in one or two batches following the detected batch. Control method of power saving operation of radio call receiver.