KR100308815B1 - Pager and Method Of Receiving Data Thereof - Google Patents

Abstract

The present invention relates to a pager for removing noise generated in received data by a main clock signal and a data receiving method thereof.

A pager according to the present invention comprises: a first oscillator for generating a low frequency subclock signal; A second oscillator for generating a high frequency main clock signal; A receiving unit connected to an antenna for receiving message data; A decoder for decoding the message data; A display unit for displaying message data; And control means for stopping the second oscillator when the message data is received by the receiver and driving the first oscillator to supply the message data decoded by the subclock signal to the display.

The present invention generates a low frequency sub clock signal to receive data by the sub clock signal.

In the pager and the data receiving method according to the present invention, since the data is received by using a subclock, the noise mixed in the received data can be minimized.

Description

Pager and Method Of Receiving Data Thereof}

The present invention relates to a pager for removing noise generated in received data by a main clock signal and a data receiving method thereof.

In general, a pager is driven by different oscillation frequencies in a state in which message data is not received and a state in which message data is received. In order to reduce power consumption in the state where no message data is received, the drive is driven at a low oscillation frequency, and when the message data is received, it is driven at a high oscillation frequency.

Referring to FIG. 1, a receiver 2, a decoder 4, and a controller 6 connected in series with an antenna 1, a display unit 8, a buzzer 10, and a motor connected in common to the controller 6. 12, a phaser with first and second oscillators 14, 16 is shown. The receiver 2 receives the message data through the antenna 1, and the decoder 4 decodes the received message data and supplies it to the controller 6. The display unit 8 is a liquid crystal display and serves to display data (time data, received message data, etc.) supplied from the control unit 6. The first oscillator 14 generates the subclock SCLK of 32.768 kHz under the control of the controller 6, and the second oscillator 16 generates the main clock MCLK of 800 kHz under the control of the controller 6. Will generate The first and second capacitors C1 and C2 connected between the first oscillator 14 and the ground voltage source GND allow the modifier of the first oscillator 14 to accurately oscillate the frequency. Similarly, the third and fourth capacitors C3 and C4 connected between the second oscillator 16 and the ground voltage source GND allow the modifier of the second oscillator 16 to oscillate the frequency accurately. The buzzer 12 and the motor 14 are driven by the main clock MCLK under the control of the controller 6 to generate a beep sound or to vibrate the pager.

The controller 6 is driven by the sub clock SCLK supplied from the first oscillator 14 in the battery safe mode in which message data is not received to display time and the like on the display unit 8. In the data receiving mode in which the message data is received, the control unit 6 recognizes the data reception by an interrupt when the message data is received, and drives the second oscillator 16. The control unit 6 receives the message data decoded by the main clock MCLK supplied from the second oscillator 16 from the decoder 4, displays the received message data through the display unit 8, and also displays a buzzer. 12 or the motor 14 is driven.

The message data receiving process in the data receiving mode will be described with reference to FIG. 2.

First, when the message data is received, the controller 6 drives the second generator 16 and clears an internal buffer (not shown) in which the message data is temporarily stored (steps S11 and S12). 6 receives the message data from the decoder 4. (Step S13) When the reception of the message data is completed, the message data is arranged in association with the received time and the time information and the message data are supplied to the display unit 8. The buzzer 10 or the motor 12 is driven at the same time as being displayed. (Steps S14 and S15)

However, in the conventional pager, when the message data is received as described above, the main clock (MCLK) is driven to receive data at a reception frequency of 300 MHz. When the data is received, the noise component is multiplied by the odd number of the main clock (MCLK). Will occur. At this time, a noise component corresponding to the reception frequency is also generated, and since the noise component is mixed in the received message data, there is a problem in that the reception rate is low. Here, the reception rate refers to how low a weak electric field data can be received without error. Normally, the main clock (MCLK) noise affects about 2 to 4 dB in the reception rate in the weak field (above -107 dB).

Accordingly, an object of the present invention is to provide a pager and a data receiving method for removing noise generated in the received data by the main clock signal.

1 is a block diagram schematically showing a conventional pager.

2 is a flowchart illustrating a conventional data receiving method step by step.

3 is a block diagram illustrating a pager according to an embodiment of the present invention.

4 is a flowchart illustrating a step-by-step method of receiving data in a pager according to an exemplary embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

1 antenna 2 receiver

4 decoder 6,26 control unit

8: display unit 10: buzzer

12: motor 14,20: first oscillator

16: second oscillator

In order to achieve the above object, a pager according to the present invention comprises: a first oscillator for generating a low frequency subclock signal; A second oscillator for generating a high frequency main clock signal; A receiving unit connected to an antenna for receiving message data; A decoder for decoding the message data; A display unit for displaying message data; And control means for stopping the second oscillator when the message data is received by the receiver and driving the first oscillator to supply the message data decoded by the subclock signal to the display.

An apparatus for removing noise in accordance with the present invention includes the steps of: generating a low frequency subclock signal; Receiving message data by a subclock signal; Stopping the oscillator generating a high frequency main clock signal when message data is received; Clearing the buffer in which the message data will be temporarily stored; After receiving the message data by the subclock signal, displaying the message data and notifying the subscriber that the message data has been received in one of a beep and a vibration form.

Other objects and features of the present invention in addition to the above object will be apparent from the description of the embodiments with reference to the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 3 and 4.

Referring to FIG. 3, the receiver 2, the decoder 4, and the controller 26 connected in series with the antenna 1, the display unit 8, the buzzer 10, and the motor connected in common to the controller 26 are illustrated. 12, a pager according to the present invention with first and second oscillators 20, 16 is shown. The receiver 2 receives the message data through the antenna 1, and the decoder 4 decodes the received message data and supplies it to the controller 26. The display unit 8 displays data (time data, received message data, etc.) supplied from the control unit 6. The first oscillator 20 generates a subclock SCLK of 76.8 kHz or 153.6 kHz under the control of the control unit 26, and the second oscillator 16 has a main clock of 800 kHz under the control of the control unit 26. Will generate (MCLK). The first and second capacitors C1 and C2 connected between the first oscillator 20 and the ground voltage source GND allow the modifier of the first oscillator 20 to accurately oscillate the corresponding frequency. Similarly, the third and fourth capacitors C3 and C4 connected between the second oscillator 16 and the ground voltage source GND allow the modifier of the second oscillator 14 to accurately oscillate the frequency. The buzzer 12 and the motor 20 are driven by the main clock MCLK under the control of the controller 26 to generate a beep sound or to vibrate the pager.

The controller 26 is driven by the sub clock SCLK supplied from the first oscillator 20 in the battery safe mode in which message data is not received to display time and the like on the display unit 8. In the data reception mode in which the message data is received, the control unit 26 recognizes the data reception by an interrupt when the message data is received, stops the second oscillator 16, and drives the first oscillator 20. Let's go. The control unit 26 receives the message data decoded by the sub clock MCLK supplied from the first oscillator 20 from the decoder 4, displays the received message data through the display unit 8, and also the buzzer. 12 or the motor 20 is driven.

The message data receiving process in the data receiving mode will be described with reference to FIG. 4.

First, when the message data is received, the control unit 26 stops the second generator 16, drives the first oscillator 20, and clears an internal buffer (not shown) in which the message data is temporarily stored. (Step S21 and S22) And the control unit 26 drives the sub clock (SCLK) supplied from the first oscillator 20 to receive the message data from the decoder 4 at a reception frequency of 300MHz. Step S23) Here, the frequency of the sub clock (SCLK) is set to 76.8kHz or 153.6kHz, 76.8kHz is 1200bps and 153.6kHz is used for 2400bps. When the reception of the message data is completed, the message data is arranged in association with the received time, the time information and the message data are supplied to the display unit 8 and displayed, and the second oscillator 16 is driven to the main clock MCLK. Thereby driving the buzzer 10 or the motor 12 (steps S24 and S25).

As described above, the pager and its data receiving method according to the present invention are received by using a subclock when receiving data, thereby minimizing noise mixed in the received data. As a result, the reception ratio is improved by about 2 to 4 dB.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (1)

A first oscillator for generating a low frequency subclock signal; A second oscillator for generating a high frequency main clock signal; A receiving unit connected to an antenna for receiving message data; A decoder for decoding the message data; A display unit for displaying the message data; And a control means for stopping the second oscillator when the message data is received by the receiver and driving the first oscillator to supply the message data decoded by the sub clock signal to the display unit. Pager to do.