KR100734111B1 - Mobile terminal for reducing current consumption in idle and system clock generation method of the mobile terminal - Google Patents

Abstract

A mobile communication terminal reducing consumption current in an idle state and a system clock generating method thereof are provided to reduce the consumption of a battery and to lengthen an idling capability time by controlling a wake duration time of a system clock according to a wireless electric wave environment. A mobile communication terminal reducing consumption current in an idle state comprises an RF receiver(10), a baseband(20), a clock controller(30) and a clock generator(40). The RF receiver(10) receives paging information from a base station. The baseband(20) calculates a paging cycle by using the paging information forwarded by the RF receiver(10), and detects information on neighbor cells. The clock controller(30) generates and outputs a clock control signal which controls generation of the system clock and a wake time of the system clock according the paging cycle and the information on the neighbor cell. The clock generator(40) generates the system clock according to the clock control signal and outputs the system clock to the RF receiver(10) and the baseband(20).

Description

MOBILE TERMINAL FOR REDUCING CURRENT CONSUMPTION IN IDLE AND SYSTEM CLOCK GENERATION METHOD OF THE MOBILE TERMINAL}

1 is a block diagram showing the configuration of a system clock generator in a conventional GSM terminal.

FIG. 2 is a waveform diagram illustrating a system clock by the system clock generator of FIG. 1. FIG.

3 is a block diagram showing the configuration of a system clock generator of a mobile communication terminal according to the present invention;

4 is a flowchart illustrating a system clock generation method of a mobile communication terminal according to the present invention.

5 is a waveform diagram showing a system clock by the system clock generator according to the present invention.

* Explanation of symbols for the main parts of the drawings

10: RF receiver 20: baseband

30: clock adjusting unit 40: clock generating unit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication terminal of a Global System For Mobile Communication (GSM) scheme, and more particularly, to wake up a system clock in a standby state according to neighbor cell information of paging information received from a base station. The present invention relates to a system clock generator of a mobile communication terminal and a method of generating the same, which reduce current consumption by adjusting a wake duration time.

In the idle state of the mobile communication terminal, the sleep state and the wake state are repeated at regular intervals to reduce current consumption. In the sleep state, the power of various devices is cut off to minimize the consumption of current. In the wake state, the mobile terminal wakes up when the power is connected to the device to receive various information and paging signals transmitted from the base station.

In the wake state in which the mobile communication terminal wakes up to receive various information and paging signals from the base station in the standby state, several times more current is consumed than in the sleep state in which the mobile terminal is sleeping.

1 is a block diagram showing the configuration of a system clock generator in a conventional GSM mobile communication terminal (hereinafter referred to as a GSM terminal).

When the base station (not shown) broadcasts the paging information through the SACCH control signal, the RF receiver 1 receives the paging information from the base station according to the paging period and transfers it to the baseband (2). The baseband 2 analyzes the paging information, calculates a paging period for synchronizing with the base station, generates a clock control signal for controlling the system clock to be enabled according to the paging period, and generates a clock generator 3. Will output The clock generator 3 controls the RF signal reception operation of the RF receiver 1 according to a paging period by generating a system clock according to the clock control signal.

That is, the GSM terminal transmits and receives information with the base station according to a paging period in a standby state, where 52 multiframes (104 frames, 235 ms) are set to 1 cycle in the standby state. It has a paging cycle. Since the calculation of the paging period can be obtained according to the GSM standard specification, a detailed description thereof will be omitted.

By the way, when controlling the system clock according to the paging period in the baseband 2, the wake time of the clock is fixed to 45 ms as shown in FIG. In addition, since the RF receiver 1 basically needs to be turned on for 18 ms, the system clock is enabled 12 ms earlier than the time when the RF receiver 1 is turned on as shown in FIG. Is enabled. The reason why the wake-up time of the system clock is fixed to 45 ms longer than the time when the RF receiver 1 is turned on is not only the cell to which the current channel is connected, but also neighbor cells. System information is continuously provided from up to six).

As such, when the wake time was fixed at 45 ,, a measurement of paging 2 based on a 800 배터리 battery yielded an approximate 119.5-hour reception latency, which applies equally to a strong or weak field. It is becoming.

Accordingly, an object of the present invention is to minimize the current consumption of a mobile communication terminal in a reception standby state by actively adjusting a wake time of the system clock according to a radio wave environment by improving a system clock generation method in a reception standby state.

Mobile communication terminal of the present invention for achieving the above object is an RF receiver for receiving paging information from the base station; A baseband for calculating a paging period and detecting neighboring cell information using the paging information from the RF receiver; A clock adjusting unit configured to generate and output a clock control signal for controlling generation of a system clock and wake time of the system clock according to the paging period and the neighboring cell information from the baseband; And a clock generator for generating the system clock according to the clock control signal and outputting the system clock to the RF receiver and the baseband.

A system clock generation method in a mobile communication terminal of the present invention includes a first step of receiving paging information from a base station; Detecting neighboring cell information from the received paging information and calculating a paging period using the paging information; And adjusting a generation of a system clock and a wake time of the system clock according to the paging period and the neighboring cell information.

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

3 is a block diagram showing the configuration of a system clock generator of a mobile communication terminal according to the present invention.

The system clock generator of FIG. 3 includes an RF receiver 10, a baseband 20, a clock controller 30, and a clock generator 40.

The RF receiver 10 receives an RF signal from a base station (not shown) through the antenna 12 and transmits the RF signal to the baseband 20. The RF receiver 10 has the same function as the RF receiver 1 in FIG.

The baseband 20 detects paging information received through a slow associated control channel (SACCH) among signals received from the base station through the RF receiver 10, calculates a paging period, and includes the calculated paging period and the paging information. Information about the neighboring cells is transferred to the clock controller 30. That is, the paging information from the base station includes a multiframe number for determining a paging period, and the baseband 20 multiplies the multiframe number by 235 ms, which is a multiframe one period time, to calculate a paging period. The multiframe number varies depending on the radio wave environment. The better the radio wave environment is, the larger the number representing the number is, and the worse the radio wave environment is, the smaller the number is.

The clock controller 30 outputs a clock control signal to the clock generator 40 to control the generation of the system clock according to the paging period and the neighboring cell information provided from the baseband 20. In this case, the clock controller 30 adjusts a wake duration time of the system clock in the reception standby state according to the number of neighboring cells. That is, as described above, the wake time of the clock is maintained at 45 ms to provide information from up to six neighboring cells in addition to the serving cell to which the current channel is connected, but when there are not many neighboring cells to receive the information. There is no need to hold the wake time for 45 seconds. Accordingly, when the neighboring cells are less than or equal to a predetermined number (for example, three), the clock control unit 30 reduces the clock control signal for reducing the wake time in the standby state from 45 kHz to 35 kHz. )

The clock generator 40 generates a system clock according to the clock control signal from the clock controller 30 and outputs the system clock to the baseband 20 and the RF receiver 10.

3 is a flowchart illustrating a system clock generation method according to the present invention.

The baseband 20 receives the paging information, which is woken according to a preset paging period and broadcasted from the base station, through the RF receiver 10 (step 410).

When the paging information is received, the baseband 20 extracts the multiframe number included in the paging information to recalculate the paging period (step 420). At this time, the baseband 20 calculates a paging period by multiplying the extracted multiframe number by 235 ms, which is a multiframe one period time. Therefore, when the radio wave environment is the same or similar, the paging period is not changed and remains the same since the multiframe numbers are the same.

After the paging period is calculated, the baseband 20 detects information on the neighboring cells included in the paging information and transmits the information to the clock controller 30 along with the paging period calculated in step 420 (step 430).

The clock controller 30, which receives the paging period and the neighboring cell information, may provide the information to itself in the current state through the received neighboring cell information before generating the clock control signal for controlling the generation of the system clock. It checks how many neighboring cells there are and compares the number with a preset number (three in this embodiment) (step 440).

As a result of the comparison, when the number of neighboring cells is larger than three, the clock adjusting unit 30 generates a clock control signal in the same manner as in the conventional baseband 2 and outputs the clock control signal to the clock generating unit 40 (step 450). ). That is, the clock controller 30 generates a clock control signal and outputs the clock control signal to the clock generator 40 to generate a system clock having a wake time of 45 ms according to the paging period provided from the baseband 20.

However, when the number of neighboring cells is less than three at step 440, the clock controller 30 generates a clock control signal for shortening the wake time of the system clock generated in the reception standby state, and then sends the clock control signal to the clock generator 40. Output (step 460).

When the clock control signal generated in step 450 or step 460 is applied, the clock generator 40 generates a system clock according to the clock signal of the baseband 20 and the RF receiver 10. In this embodiment, as shown in FIG. 5, the wake time of the system clock is reduced from 45 s to 35 s by keeping the enable time of the system clock as it is and by 10 s earlier.

As such, by adjusting the wake time of the system clock according to the radio wave environment, that is, the number of neighboring cells in the reception standby state, it is possible to listen for about 140.5 hours as measured by paging 2 based on a battery of 800 ㎃. It can be seen that the standby time is increased by 21 hours (about 1 day) than the conventional 119.5 hours under the same conditions.

As described above, the mobile communication terminal of the present invention can reduce the battery consumption by adjusting the wake time of the system clock according to the radio wave environment, thereby extending the reception standby time of the mobile communication terminal.

Claims (8)

An RF receiver for receiving paging information from a base station; A baseband for calculating a paging period and detecting neighboring cell information using the paging information from the RF receiver; A clock adjusting unit configured to generate and output a clock control signal for controlling generation of a system clock and wake time of the system clock according to the paging period and the neighboring cell information from the baseband; And A mobile communication terminal for reducing the current consumption in the standby standby state comprising the clock generator for generating the system clock according to the clock control signal and outputs to the RF receiver and the baseband. The method of claim 1, wherein the baseband And a paging period is calculated by multiplying the multiframe number included in the paging information by a multiframe 1 period time. The method of claim 1, wherein the clock control unit A mobile communication terminal for reducing the current consumption in the standby standby state, characterized in that for adjusting the wake time of the system clock according to the number of the neighboring cells. The clock control unit of claim 3, wherein the clock controller The wake-up time is shortened when the number of the neighboring cell is smaller than a predetermined number, the mobile communication terminal to reduce the current consumption in the standby standby state. A first step of receiving paging information from a base station; Detecting neighboring cell information from the received paging information and calculating a paging period using the paging information; And And a third step of adjusting a generation time of the system clock and a wake time of the system clock according to the paging period and the neighboring cell information. The method of claim 5, wherein the second step And detecting the number of neighbor cells from the information of the neighbor cells. The method of claim 6, wherein the third step And shortening the wake time when the number of neighboring cells is smaller than a predetermined specific number. The method of claim 5, wherein the second step And detecting the multiframe number from the paging information and multiplying the multiframe number by one multiframe period to calculate the paging period.

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