KR0165615B1 - Mobile subscriber having power saving function receiving bcch channel - Google Patents

Abstract

According to the present invention, in a personal communication terminal having a power saving function, a power for repetitive reception of broadcast information on a channel configuration in an already connected base station when the connection with a specific base station is repeated when the terminal is not moved is repeated. The present invention relates to a personal communication terminal having a power saving function of a broadcast control channel receiving power that can be saved. The personal communication terminal operated by a TDMA method according to the GSM standard, comprising: receiving an original code signal from a radio frequency signal received by an antenna. Demodulation means for demodulating, baseband processing means for performing decoding and deinterleaving on the code data restored by the demodulator, and controlling the broadcast channel transmitted from the base station by processing data output from the baseband processing means. LAPDm processing means for detecting data, the broadcast channel B processed by this LAPDm processing means Broadcast information storage means for storing broadcast information of the corresponding base station through control data of the CCH, and in connection with a control station having broadcast information stored in the broadcast information storage means, based on the stored broadcast information without receiving a broadcast channel. And control means for controlling execution of the connection with the base station.

Description

Personal communication terminal with power saving function of broadcasting control channel

1 is a system configuration diagram showing the overall configuration of a personal communication system.

2 is a configuration diagram showing a frame structure of transmission / reception data in the personal communication system shown in FIG.

3 is a data configuration diagram of a traffic channel for transmitting and receiving voice data between a base station and a terminal in the personal communication system shown in FIG.

4 is a data configuration diagram of a control channel for transmitting and receiving control data to and from a base station and a terminal in the personal communication system shown in FIG.

5 is a block diagram showing the configuration of a personal communication terminal having a broadcast control channel reception power saving function according to an embodiment of the present invention.

6 is an operational flowchart for explaining the operation of the apparatus according to the present invention.

* Explanation of symbols for main parts of the drawings

1: terminal 2 (2 ₁ ~ 2n): base station

3 (3 ₁ to 3n): base station controller 4: switchboard

5: Certification Center 21: Demodulation

22: low noise amplifier 23: demodulator

24: baseband processing unit 25: LAPDm processing unit

26: speaker 27: microphone

28: voice processing unit 29: modulator

30: amplification unit 31: key input unit

32: display unit 33: control unit

34: program memory 35: data memory

36: A / D converter 37: broadcasting information storage unit

The present invention relates to a personal communication terminal with a built-in power saving function. In particular, when a connection with a specific base station is repeated when the terminal is in a non-mobile state, the present invention relates to the repeated reception of broadcast information about a channel configuration in a base station that is connected. The present invention relates to a personal communication terminal having a power saving function of a broadcast control channel receiving power that can save power.

Recently, with the rapid development of communication technology, a personal communication system has been developed and generalized so that an individual can communicate with another person while moving from an arbitrary place or from one place to another.

Such a personal communication system is largely divided into a time division multiple access (TDMA) method and a code multiple access (CDMA) method, and the TDMA method is widely used worldwide because of the high stability of the system and completeness of technology.

1 is a configuration diagram schematically showing the configuration of a personal communication system, in particular a TDMA system according to the TDMA method, in which reference numeral 1 denotes a terminal to be carried by an individual, and 2 (2 ₁ to 2n) denotes a plurality of terminals ( 1) A base station which transmits and receives various data and transmits and receives a radio signal to the terminal 1, and converts and encrypts / decrypts a communication protocol, and 3 (3 ₁ to 3n) are a plurality of base stations (2: 2 ₁ to 2). 2n), the base station controller which performs functions such as allocation control and handover decision of the communication channel for each terminal 1, and the base station controller 3 and the trunk line or the local exchange are subsequently connected. An exchange that connects the authentication center 5 to be described, 5 is an authentication center that executes a license and charge processing for any terminal 1 by providing a unique number for each terminal 1 and the like.

In the personal communication system having the above configuration, when any terminal 1 is located in a specific area, the base station 2 having jurisdiction over the area confirms the existence of the terminal 1 and reports it to the base station controller 3. The base station controller 3 checks the registration status of the terminal 1 from the authentication center 5 and then assigns an encryption code or the like necessary for a call through the base station 2 to enable the corresponding terminal 1 to be used. In addition to the set to, it is connected to the corresponding terminal 1 by a call or the like from the other terminal (1).

In the above-described personal communication system, however, the base station 2 and the terminal 1 transmit and receive data through wireless communication, so that the base station 2 and the terminal 1 are provided. In order to transmit / receive data between them, it is necessary to match the transmission / reception method or the specification of the transmission / reception data. In view of this point, in general, in a TDMA personal communication system, the system is configured according to the GSM (Global System for Mobile communication) standard.

According to the GSM standard, the base station controller 3 and the base station 2 transmit and receive data according to the LAPD protocol, and the base station 2 and the terminal 1 perform the LAPDm protocol.

In addition, according to the GSM standard, each base station (or terminal) has four radio carriers for data transmission and reception, and eight time slots (TS) for each radio carrier, and each time slot is 156.25. In this case, each time slot is allocated by the base station controller 3 for transmission of control data and traffic data of the terminal.

In addition, the base station 2 and the terminal 1 operate on the basis of a 13 MHz clock so that each bit constituting the timeslot TS has a length of 48 clocks, and as shown in FIG. Eight timeslots (TS) are used as one frame, and 51-multiframe or 102-multiframe including 51 or 102 frames for control data and 26 frames for traffic data (voice and data) It consists of a 26-multiframe including, and collects the 26-multiframe 51 or the 51-multiframe 26 or 102-multiframe 13 to form a super frame (Super Frame) .

In the above configuration, the base station 2 transmits to each terminal 1 a frame start signal for indicating the start time of the data frame and a time slot number to be used, and each terminal 1 transmits the frame start signal. By synchronizing the transmission and reception of data with the base station 2 on the basis of the above, and transmitting and receiving various data, for example, voice data or control data, with the base station 2 through the allocated time slot period of each data frame. It is intended to provide a call function to the user.

FIG. 3 is a data configuration diagram showing a 26-multiframe configuration of a traffic channel for transmitting and receiving voice data between the base station 2 and the terminal 1. In FIG. Figure 1 shows the relationship between the data frame transmitted from 1) and the data frame transmitted from the terminal 1 to the base station 2, and (b) and (c) represent data received through the timeslot assigned to the specific terminal. (B) shows a case in which one terminal uses one timeslot, and (c) shows a time slot shared by two terminals. The case of use is shown.

As shown in FIG. 3 (a), in the personal communication system, the downlink and the uplink have a frequency difference of 90 MHz, and the uplink is a shifted time slot of three timeslots with respect to the downlink. The time slot is set automatically.

That is, according to the GSM standard, when the terminal 1 is assigned a frequency for the downlink and its timeslot number by the base station controller 3, the terminal 1 is upgraded to a time slot delayed by 90 MHz for the downlink frequency and a 3 timeslot delayed time slot. It is intended to set the frequency and timeslot for the link.

As shown in FIG. 3 (b), after transmitting the traffic channel T through 12 timeslots, i.e., 12 frames, the terminal 1 and the base station 2 adjust timing according to the transmission / reception distance. After transmitting the Slow Associateed Control Channel (A), and again transmitting 12 voice channels, a time slot for idle is allocated.

In addition, as shown in FIG. 3 (c), when one time slot is shared and used by two terminals, that is, in the case of a half rate method, 12 traffic channels T and t are transmitted. The low speed coupled control channel A for one terminal is transmitted, and then the twelve traffic channels T and t are transmitted again, followed by the low speed coupled control channel a for the second terminal.

On the other hand, Figure 4 shows the configuration of the 51-multiframe of the control channel for transmitting and receiving control data between the base station 2 and the terminal 1, which is shown in Figure 3 (b) and (c) The result of gathering the data received through the timeslot assigned to it is shown.

In FIG. 4, reference numeral F denotes a frequency correction channel (FCCH) for frequency correction of the terminal, S denotes a synchronization channel (SCH) for the terminal to synchronize frame synchronization with the base station, and B denotes a base station for the terminal. A broadcast control channel (BCCH) for transmitting various data for a terminal to access a base station, such as various states of the base station and information of neighboring base stations, and C is an access permission channel (AGCH) for a response to an outgoing request from the terminal. Or a common control channel (CCCH) for transmitting and receiving various control data, such as a call channel (PCH) for transmitting a call signal to a terminal, a fast combined control channel (FACCH) for a handover function, and the like. A random access channel (RACH) for requesting an outgoing call or responding to a call signal from a base station, D0 to D7 performs authentication or call setup to register a terminal. Independent control channel (SDCCH) for transmitting and receiving various control data related to the transmission and reception, A0 ~ A7 transmits and receives the signal strength and timing advance value of the signal transmitted / received by the terminal to the base station or during communication with another terminal As a low speed coupled control channel (SACCH), in the personal communication system, various control data necessary for transmission and reception are transmitted and received by combining the various control channels as shown in FIG.

On the other hand, the terminal 1 is configured to drive the internal transmitter and receiver only during the transmission and reception time intervals of the self timeslot allocated based on the clock synchronized with the base station 2, wherein the power consumed by the terminal is wireless. The power consumption is the largest in the signal transmission section, followed by the frequency synthesis section for high frequency synthesis, the driving of the demodulation stage for reception, and the baseband processing.

In addition, the base station 2 transmits various data for the terminal 1 to connect to the base station 2, such as various states of the base station, information of neighboring base stations, etc. with respect to the terminal 1, Since the logical channel is a broadcast control channel (BCCH), the reception of the broadcast control channel is not information that changes frequently in connection from a specific base station 2, so that the subscriber can use the terminal fixedly without changing the position in one place. If there is, there is a problem that unnecessary power is wasted because the receiving operation of the same information is repeated in the reception of the information transmitted from the base station 2.

Accordingly, the present invention has been made in view of the above-described circumstances, and in the case where the connection with a specific base station is repeated when the terminal is in a non-mobile state, the power for repetitive reception of broadcast information on the channel configuration in the already connected base station The purpose of the present invention is to provide a personal communication terminal having a reception power saving function in a broadcast control channel that can save the cost.

A personal communication terminal having a broadcast control channel reception power saving function according to the present invention for realizing the above object is an original code from a radio frequency signal received by an antenna in a personal communication terminal operated by a TDMA method according to the GSM standard. Demodulation means for demodulating a signal, baseband processing means for decoding and deinterleaving the code data restored by the demodulation unit, and processing the data output from the baseband processing means to a broadcast channel transmitted from a base station. LAPDm processing means for detecting the control data for the broadcast information, broadcast information storage means for storing the broadcast information of the base station through the control data of the broadcast channel (BCCH) processed by the LAPDm processing means, and stored in the broadcast information storage means When connected to a control station with broadcast information, the room is stored without receiving the broadcast channel. Based on the information, including control means for executing controlling the connection with the base station it is characterized in that configured.

That is, according to the present invention having the above-described configuration, the terminal transmits various data for accessing the base station, such as various states of the base station transmitted from the base station to the terminal, information of neighboring base stations, and the like. The broadcast control channel (BCCH), which is used for a broadcast channel (BCCH) which is continuously received after receiving the frequency correction channel (FCCH) and the synchronization channel (SCH) as shown in FIG. By storing the broadcast information to be accessed once and storing it, connection with the base station is executed based on the stored broadcast information without receiving the same broadcast information, thereby saving power during the reception of broadcast information.

Hereinafter, with reference to the accompanying drawings will be described an embodiment according to the present invention.

5 is a block diagram illustrating a personal communication terminal having a power saving function of a broadcast control channel reception power according to an embodiment of the present invention. In the drawing, reference numeral 21 denotes an antenna for transmitting and receiving data with the base station 2, and A low noise amplifier comprising a low noise amplifier for amplifying the frequency signal received by the antenna 21 and the like, 23 demodulates an original code signal from a frequency signal input through the low noise amplifier 22. A demodulation section comprising a demodulation section 231 and a modulation section for modulating the transmission data output through the baseband processing section 24 to be described later into a predetermined frequency signal.

Also, reference numeral 24 denotes a baseband processor for executing interleaving, block coding, and convolutional coding for data transmitted and received through the modulation / demodulation unit 23 according to a GSM standard. Is a LAPDm processing unit for processing control data transmitted and received with the base station 2 according to the LAPDm standard.

Further, reference numeral 26 denotes a speaker for outputting an audio signal from an opposite station terminal as an audible voice, 27 is a microphone for converting and inputting a user's voice input as an electrical voice signal, and 28 is an analog input from the microphone 27. A voice processor converts a voice signal into digital data, and converts voice data applied through the baseband processor 24 into an analog voice signal and outputs the voice signal to the speaker 26.

Further, reference numeral 29 denotes an amplifier which amplifies the frequency signal transmitted from the modulation / demodulation unit 23.

Reference numeral 30 denotes a key input unit having a plurality of (10-keys) and function keys, 31 denotes a display unit such as a liquid crystal display device for displaying various operation states or operation states of the terminal 1, and A control unit for controlling the terminal 1 according to an operation signal input through the key input unit 30 while controlling the operation state of the terminal through transmission and reception with the base station 2 through the LAPDm processing unit 25; 33 is a program memory in which the operation program of the control unit 32 is stored, and 34 is a data memory in which various processing data related to the operation of the control unit 32 are stored.

Further, reference numeral 35 denotes an analog / digital converter for digitally converting the received data demodulated and output from the demodulation and demodulation unit 23 and outputting a data value corresponding to the received power level to the control unit 32. It is provided for base station selection or handover function.

On the other hand, reference numeral 36 is a broadcast information unit for storing broadcast information from the base station when the broadcast channel (BCCH) is received by the baseband processing unit 24.

Next, the operation of the apparatus having the above-described configuration will be described using the flowchart shown in FIG.

When the user turns on the power of the terminal 1 (step ST1), the controller 33 searches for a radio carrier received through the antenna 21 while sequentially increasing or decreasing the demodulation frequency of the demodulator 231. In addition, (ST2 step), the base station 2 to which it belongs is identified based on the level of each demodulation signal input through the analog / digital converter 35 (step ST3).

If the base station determined accordingly is not the base station already connected to the terminal (ST4 step), the control unit 33 inputs the control data for controlling the demodulation unit 23 and accordingly through the analog / digital converter 35. After the level value of the received data is stored in the data memory 31, the demodulation frequency of the demodulation unit 23 is set based on the reception frequency having the largest level value.

The control unit 32 receives the broadcast channel from the base station 2 received by the modulation and demodulation unit 23 to grasp information of the corresponding base station, and the baseband processing unit 24 receives the information of the base station. After storing in the broadcast signal storage unit 37 (steps ST5 and ST6), the LAPDm processor 25, the baseband processor 24, and the modulation / demodulator 23 transmit their information to the corresponding base station for registration. The procedure is performed (ST7 step).

On the other hand, in the case of the base station that is already connected to the terminal in step ST4, the registration procedure is performed by transmitting its own information to the corresponding base station as in step ST7 without repetitive reception of the broadcast channel transmitted from the same base station.

Meanwhile, when the base station 2 receives the terminal information from the terminal 1, the base station 2 transmits the terminal information to the base station controller 3, and the base station controller 3 transmits the terminal information to the authentication center 5 through the exchange 4. By transmitting to the terminal, it is confirmed whether the terminal 1 is legally registered.

When it is determined that the terminal 1 is normally registered, the base station controller 3 sends the encryption code or the like to the terminal 1 through the base station 2 to make the terminal 1 available. In addition to registration processing, subsequent call processing from other terminals is executed.

On the other hand, when the registration processing is completed in step ST7, the control unit 32 determines whether there is a call from another terminal, that is, whether a paging channel is received from the base station 2, or the user operates the key input unit 30. To detect whether a handover command is received from the base station 2 (ST8 to ST10).

When the call channel is received in step ST8, the call response is performed to the base station 2 (step ST11) and the alarm signal output unit of the terminal is driven to indicate that the user has a call from another terminal. If the user requests transmission in step ST9, the controller detects a key input from the key input unit 30 (step ST12), and then transmits a random access channel (RACH) to the base station 2. The connection request is executed (step ST13).

At this time, when the access permission channel (AGCH) is received from the base station 2 or after executing the call response in step ST13, the user and the user of the other terminal can make a call by transmitting and receiving a voice signal through the assigned time slot. (ST14).

When the call is terminated (step ST15), the process returns to step ST8 to continuously monitor whether the call channel is received, whether to request transmission, or handover.

In addition, when a handover command is received from the base station in step ST10 due to the user moving to another area, the handover process is executed by executing the connection process for the other base station based on the newly provided base station information ( ST16 step).

That is, according to the above embodiment, the terminal transmits various data for accessing the base station such as various states of the base station transmitted from the base station to the terminal and information of neighboring base stations, and the logical channel used at this time is the broadcast control channel. As shown in FIG. 4 (a), the terminal receives broadcast information used for a broadcast channel (BCCH) which is continuously received after receiving a frequency correction channel (FCCH) and a synchronization channel (SCH). By storing after accessing once, since the connection with the base station is performed based on the stored broadcast information without receiving the same broadcast information, it is possible to save power while receiving broadcast information.

In addition, this invention is not limited to the said Example, It can implement in a various deformation | transformation in the range which does not deviate from the technical summary of this invention.

As described above, according to the present invention, when the connection with a specific base station is repeated when the terminal is in a non-mobile state, it is possible to save power for repetitive reception of broadcast information on a channel configuration in a base station that is already connected. It is possible to realize a personal communication terminal having a broadcast control channel reception power saving function.

Claims (1)

A personal communication terminal operating in a TDMA manner according to the GSM standard, comprising: demodulation means for demodulating an original code signal from a radio frequency signal received by an antenna, and decoding and deinterleaving the code data restored by the demodulation unit; Baseband processing means for executing the data, LAPDm processing means for processing data output from the baseband processing means, and detecting control data for the broadcast channel transmitted from the base station, and a broadcast channel (BCCH) processed by the LAPDm processing means. Broadcast information storage means for storing broadcast information of the base station through control data of the base station, and in connection with a control station having broadcast information stored in the broadcast information storage means, the base station based on the stored broadcast information without receiving a broadcast channel. And control means for controlling the execution of the connection therewith. Personal communication terminal capable of receiving the control channel power saving feature.