KR19990014666U - Mobile communication device - Google Patents

Abstract

The present invention relates to a mobile communication device, comprising: a detector for detecting whether a code signal matching a recognition code is included in an over-the-air signal received in a standby mode, and a code signal matching a recognition code in a standby mode Is detected, the control unit activates a component that is not activated in the standby mode to switch to the first standby mode, and in the second standby mode, only the detection unit and the control unit are activated, so that the airwave signal is transmitted in the standby mode of the mobile phone. It enables the reception of over-the-air signals without activating the components involved in the reception, thus reducing the power consumption in the standby mode.

Description

Mobile communication device

The present invention relates to a mobile communication device, and more particularly to a mobile communication device to reduce the time of the standby mode in which most of the components are activated to prevent unnecessary power consumption.

A typical mobile communication device is a cellular phone, and FIG. 1 shows a block unit configuration of a conventional mobile phone. The antenna 1 is for transmitting and receiving over-the-air signals. The RF block 2 lowers the received over-the-air signal (about 900 MHz RF) to the intermediate frequency band and outputs it to the next baseband block 3. The baseband block 3 converts a signal in the intermediate frequency band into a digital signal in the baseband band. The digital signal generated in the baseband block 3 is converted into an audio signal through a digital signal processing process through the mobile station modem 4 and output to the speaker 6. The process until the voice signal input through the microphone 5 is output in the form of an air wave signal is performed in the reverse order of the process of converting the above-described air wave signal into a voice signal.

Such mobile phones use a rechargeable battery as a power source, and various methods are used to prevent unnecessary power consumption in order to maximize the use time of the battery.

The most common of these methods is a method of dividing an operation mode of a mobile phone into a sleep mode, a standby mode, and a transmission / reception mode, and inactivating some components of the mobile communication device according to each mode to prevent unnecessary power consumption.

2 is a view showing the operation mode of such a conventional mobile phone. As shown in Fig. 2, each operation mode is mutually switched between the sleep mode and the standby mode, and mutually switched between the standby mode and the transmission / reception mode.

In the sleep mode of FIG. 2, most of the transmission / reception related components including the RF block 2, the baseband block 3, and the mobile station modem 4 shown in FIG. In the standby mode, the components related to the reception of over-the-air signals are activated so that only over-the-air signals can be received. In the transmission / reception mode, all components related to transmission and reception are activated to transmit and receive over-the-air signals.

In the standby mode of the operation mode of the conventional mobile phone, the components related to the reception of the airwave signal must be always activated, thereby causing power consumption. However, since this power consumption is not the power consumption of transmitting and receiving actual over-the-air signals, a new method for suppressing the power consumption occurring in this standby mode is required.

Accordingly, an object of the present invention is to reduce power consumption in the standby mode by enabling the reception of the airwave signal without activating a component related to the reception of the airwave signal in the standby mode of the cellular phone.

1 is a block diagram showing the configuration of a conventional cellular phone.

2 is a view showing an operation mode of a conventional cellular phone.

Figure 3 is a block diagram showing the configuration of a mobile phone according to the present invention.

4 is a view showing an operation mode of a mobile phone according to the present invention.

Explanation of symbols on the main parts of the drawings

1, 7: antenna 2, 11: RF block

3, 12: baseband block 4, 13: mobile station modem

5, 14: microphone 6, 15: speaker

8 switch 9 detection unit

10: control unit

The present invention has a detection unit for detecting whether a code signal matching the recognition code is included in the airwave signal received in the standby mode, and when a code signal matching the recognition code is detected in the standby mode And a controller for activating a component that is not activated in the mode state to switch to the first standby mode, and in the second standby mode, only the detector and the controller are activated.

Referring to Figures 3 and 4 a preferred embodiment of the present invention made as described above are as follows.

3 is a block diagram showing the configuration of a mobile telephone according to the present invention. As shown in FIG.

In the general transmission / reception mode, the airwave signals received through the antenna 7 are input to the detector 9 and the controller 10, respectively, between the antenna 7 and the detector 9, the antenna 7, and the controller 10. The path is controlled by the controller 10. The RF block 11 lowers the received over-the-air signal (about 900 MHz RF) to the intermediate frequency band and outputs it to the next baseband block 12. The baseband block 12 converts a signal in the intermediate frequency band into a digital signal in the baseband band. The digital signal generated in the baseband block 12 is converted into an audio signal through a digital signal processing process through the mobile station modem 13 and output to the speaker 15. The process until the voice signal input through the microphone 14 is output in the form of an airwave signal is performed in the reverse order of the process of converting the above-mentioned airwave signal into a voice signal.

However, in the standby mode, all components related to the reception of the airwave signal, that is, the RF block 11, the baseband block 12, the mobile station modem 13, and the like are all deactivated. However, the detection unit 9 and the control unit 10 are activated to detect the code signal of the airwave signal received through the antenna 7. This code signal is compared with a unique recognition code assigned to the mobile communication device of the present invention, and the received airwave signal is processed only when it matches, and if it does not match, the received airwave signal is destroyed.

When the switch 8 is connected to the antenna 7 and the detector 9 and the code signal included in the received airwave signal and the recognition code coincide with each other and the detection unit 9 detects the detection signal ( 9, it informs the control unit 10. The control unit 10 generates an activation signal EN to activate components related to the reception of airwave signals such as the RF block 11, the baseband block 12, and the mobile station modem 13. When such components related to air signal reception are activated, the controller 10 operates the switch 8 so that the antenna 7 and the controller 10 are connected to the RF block to receive the air signals received through the antenna 7. Deliver to 11. The RF block 11 receiving the airwave signal from the control unit 10 lowers the received airwave signal (RF about 900MHz) to the intermediate frequency band and outputs it to the baseband block 12 of the next stage. The baseband block 12 converts a signal in the intermediate frequency band into a digital signal in the baseband band. The digital signal generated in the baseband block 12 is converted into an audio signal through a digital signal processing process through the mobile station modem 13 and output to the speaker 15.

4 is a view showing an operation mode of a mobile phone according to the present invention. As can be seen in Figure 4, there is a standby mode II between the sleep mode and the standby mode I. In the standby mode II, only the detection unit 9 and the control unit 10 for detecting the code signal of the received air wave signal are activated instead of the reception related components generally activated in the standby mode. When the detection unit 9 receives an airwave signal including a code signal matching the recognition code, the control unit 10 switches the mobile communication device according to the present invention to the standby mode I to activate most of the reception-related components. In this case, normal over-the-air signals are received.

Therefore, the present invention can reduce the power consumption in the standby mode by enabling the reception of the over-the-air signals without activating components related to the reception of the over-the-air signals in the standby mode of the cellular phone.

Claims (1)

Transmit and receive airwave signals through an antenna, and have a unique identification code assigned to it, include a receiver and a transmitter, and some of the components including the receiver and the transmitter are not activated, and thus the airwave signals cannot be transmitted or received. In a mobile communication device having a mode and a first standby mode in which a part of a component including the receiver and the transmitter is activated to transmit and receive the over-the-air signal, and a transmit / receive mode in which the over-the-air signal is actually transmitted and received. , A detection unit which detects whether a code signal matching the recognition code is included in the received airwave signal in the standby mode; In the standby mode, if a code signal matching the recognition code is detected, and a control unit for activating a component that is not activated in the standby mode to switch to the first standby mode, And a second standby mode in which only the detector and the controller are activated.