JP2007235281A - Inter-channel synchronization method in digital wireless base station and inter-channel synchronization program in digital wireless base station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inter-channel synchronization method in a digital wireless base station wherein accurate synchronization can be taken between a reception frame and a transmission frame. <P>SOLUTION: The reception frame is configured on the basis of a received signal received by a digital signal processor 3-A at a receiver side of the digital wireless base station, a digital signal processor 3-B at a transmitter side in the digital wireless base station configures the transmission frame based on the reception frame, a transmission timing signal ta is generated at a predetermined time from a head timing of a first frame of the reception frame, and when the transmission timing signal ta is received, the digital signal processor 3-B of the transmitter side transmits the transmission frame so as to take synchronization between the reception frame and the transmission frame. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an inter-channel synchronization method in a digital radio base station such as a repeater.

  A digital signal processor DSP process in a conventional digital radio base station such as a so-called repeater that relays transmission information from a business radio terminal and retransmits it to another business radio terminal is, for example, as shown in a block diagram of FIG. The 2ndIF signal obtained from the commercial wireless terminal is amplified by the amplifier 1 and converted by the A / D converter 2, and then input to one digital signal processor DSP3 and obtained from the input signal. The frame data is formed into a frame, a transmission frame is formed, converted into an analog signal by the encoder 4, amplified by the amplifier 6 via the switch circuit 5, attenuated to a predetermined level by the attenuator 7, and the control voltage of the VCO 8 As a result, modulation was performed and the modulated output was transmitted after being amplified.

  Here, by changing the free-running frequency of the VCO 8, the frequency of the output with respect to the input can be changed, that is, the channel can be changed. Further, for example, symbol data modulated by Nyquist four-value FSK is used, but the modulation method is not limited to this.

On the other hand, in digital radio base stations, digital processing is performed on the receiving side due to specification reasons such as limitations on the number of I / O ports and processing capacity problems, or because signal processing is divided between the receiving side and the transmitting side. As shown in FIG. 7, such as the signal processor DSP 3-1 and the digital signal processor DSP 3-2 that performs transmission side processing, the digital signal processor DSP performs serial communication or parallel communication between the digital signal processors DSP. There are some that send and receive data.
In addition, as an operation of a conventional digital radio station, the base station and the mobile station communicate with each other by the slot Aloha method in order to enable efficient and high-throughput random access control. An offset time of 1.5 frames is set between the downlink communication frame and the uplink communication frame, and the base station responds to the transmission permission signal I when any frame in the uplink communication frame is an empty line. When the mobile station has the transmission data, the mobile station receives the transmission permission signal I in the reception state, switches to the transmission state, and transmits the head data for one frame in the upstream frame. When the base station permits continuous transmission of subsequent data of the head data, the base station transmits continuous transmission permission information P to the mobile device, and transmits a transmission prohibition signal B to other mobile devices during the continuous transmission. There is one that receives the continuous transmission permission signal P, switches to the transmission mode, and transmits subsequent data in a plurality of consecutive frames of uplink communication frames. (For example, refer to Patent Document 1).
JP 2005-101990 A

  However, as shown in FIG. 6, if a single digital signal processor DSP is used and the timing is managed only by this digital signal processor DSP, the timing between the reception frame and the transmission frame can be taken and reception is possible. Although the transmission frame can be synchronized with the frame, there is a problem in that synchronization cannot be achieved when there are a plurality of reception frames and transmission frames.

  Further, as shown in FIG. 7, when a plurality of digital signal processors DSP are used, the digital signal processors DSP are accurately synchronized between the reception frame and the transmission frame only by serial communication and parallel communication. There was a problem that it was not possible.

  However, in the digital radio base station, accurate synchronization is required between the reception frame, the transmission frame, and the channel.

  An object of the present invention is to provide an inter-channel synchronization method in a digital radio base station that can accurately synchronize between a reception frame and a transmission frame.

  According to a first aspect of the present invention, there is provided an inter-channel synchronization method in a digital radio base station that configures a reception frame based on a reception signal received by a digital signal processor on a reception side in the digital radio base station, The frame is configured by a digital signal processor on the transmission side in the digital radio base station, and a transmission timing signal is generated and transmitted at a predetermined time from the start timing of the first frame of the reception frame or after the reception frame is configured. A transmission frame is transmitted from the digital signal processor on the transmission side when receiving the timing signal.

  According to the inter-channel synchronization method in the digital radio base station according to claim 1 of the present invention, the transmission timing signal generated at a predetermined time from the start timing of the first frame of the received frame or after the configuration of the received frame Is received, the transmission frame is transmitted from the digital signal processor on the transmission side, so that the reception frame and the transmission frame are synchronized.

  Hereinafter, an inter-channel synchronization method in a digital radio base station according to the present invention will be described with reference to embodiments.

  A solid line in FIG. 1 is a block diagram for explaining an inter-channel synchronization method in the digital radio base station according to the embodiment of the present invention. In the digital radio base station according to this embodiment, the case where the signal from the digital signal processor DSP-A on the receiving side becomes a timing reference for synchronization is illustrated.

  The digital radio base station according to the embodiment of the present invention includes a digital signal processor DSP-A that performs processing on the reception side and a digital signal processor DSP-B that performs processing on the transmission side. The 2nd IF signal obtained from the commercial wireless terminal is amplified by the amplifier 1 and converted by the A / D converter 2, and then input to the digital signal processor DSP-A and demodulated. The acquired symbol data is transmitted to the digital signal processor DSP-B by serial communication or parallel communication, and the digital signal processor DSP-B forms a transmission frame from the reception frame and transmits it based on the transmission timing. The transmission frame output from the digital signal processor DSP-B is converted into an analog signal by the codec 4, amplified by the amplifier 6 through the switch circuit 5, attenuated to a predetermined level by the attenuator 7, and supplied as a control voltage for the VCO 8. Then, the modulated output is amplified and transmitted.

  Further, the frequency of the output relative to the input can be changed by changing the free-running frequency of the VCO 8, that is, the channel can be changed, and the symbol data that has been modulated by, for example, Nyquist quaternary FSK is used. However, the modulation method is not limited to this, as in the conventional case.

  Here, the frame is composed of a synchronization word, link information data, low-speed information channel data, low-speed information channel data, and symbol data from the beginning, the frame period length is a fixed period, and the output timing of the transmission frame is digital. The transmission timing signal ta is managed by the signal processor DSP-A, and is transmitted from the digital signal processor DSP-A to the digital signal processor DSP-B at a time delayed by, for example, 11/2 frame period from the head of the first frame of the received frame. Is done. The digital signal processor DSP-B that has received the transmission timing signal ta transmits the first frame of the transmission frame from the time when the transmission timing signal ta is received.

  More specifically, in the digital radio base station, a reception frame (downstream signal) is formed by the digital signal processor DSP-A based on the received signal, and a transmission frame (upstream signal) is framed by the digital signal processor DSP-B. Configured and sent. The temporal relationship between the reception frame and the transmission frame, that is, the timing between the upstream and downstream frames is as schematically shown in FIG. 2, and synchronization is maintained.

  The flow of processing in this case is schematically shown in FIG. As shown in FIG. 3, the data and command of the transmission frame are transmitted to the digital signal processor DSP-B based on the reception frame constituted by the digital signal processor DSP-A that has received the reception 2ndIF signal (step S1). A transmission timing signal ta is generated and sent to the digital signal processor DSP-B when the 11/2 frame period has elapsed from the beginning of the first received frame (step S2).

  The digital signal processor DSP-B receives the symbol data and command transmitted from the digital signal processor DSP-A and is set in the digital signal processor DSP-B. The digital signal processor DSP-B forms a transmission frame and transmits it. The process waits and then waits for the transmission timing signal ta to be transmitted from the digital signal processor DSP-A (step S3). Next, when the transmission timing signal ta is transmitted from the digital signal processor DSP-B, the transmission timing signal ta is received by an interrupt (step S4), and the digital signal processor DSP-B receiving the transmission timing signal ta By the notification, the correction time for transmission is reflected (step S5), and transmission of the transmission frame is started (step S6).

  Therefore, the transmission frame is transmitted based on the uplink / downlink frame timing shown in FIG. 2, and synchronization is established between the reception frame and the transmission frame.

  Next, instead of the case where the signal from the receiving-side digital signal processor DSP-A becomes a timing reference for synchronization as described above, the timing clock circuit 9 indicated by the broken line in FIG. 1 sends the digital signal processor DSPb from the outside. A case where the transmission frame transmission timing is determined based on the supplied timing signal ta will be described.

  The flow of processing in this case is schematically shown in FIG. As shown in FIG. 4, the symbol data and the command are transmitted to the digital signal processor DSP-B by the reception frame configured by the digital signal processor DSP-A that has received the reception 2ndIF signal. (Step S11).

  In the digital signal processor DSP-B, the symbol data and command transmitted from the digital signal processor DSP-A are received and set in the digital signal processor DSP-B, or the data and command of the transmission frame are digitally converted by the upper layer. The signal processor DSP-B is set, and the digital signal processor DSP-B is configured to transmit a transmission frame and waits for transmission, and then waits for transmission timing signal ta from the external clock circuit 9 (step S13). . Next, when the transmission timing signal ta is transmitted from the external clock circuit 9, the transmission timing signal ta is received by interruption (step S14), and the digital signal processor DSP-B that receives the transmission timing signal ta receives the notification. The correction time for transmission is reflected (step S15), and transmission of a transmission frame is started (step S16).

  Therefore, the transmission frame is transmitted based on the uplink / downlink frame timing shown in FIG. 2, and synchronization is established between the reception frame and the transmission frame.

Processing can also be performed by one digital signal processor DSP-A. In this case, a transmission frame is generated based on the created reception frame and waits, and the transmission frame is transmitted from the digital signal processor DSP-A when the reception frame is delayed by, for example, a 11/2 frame period. That's fine.
The transmission timing is performed by the Ta signal in FIG. The Ta signal has been notified of the timing to be transmitted by the “synchronization word” of the frame received by the digital signal processor DSP-A.
Similarly, Ta is used from the timing clock circuit 9 indicated by a broken line in FIG. A timing clock Ta from the timing clock circuit 9 indicated by a broken line in FIG. 1 is a clock that generates a signal at regular intervals.
As an example, it is assumed that an input signal is generated at intervals of the frame length (T (ms) in FIG. 2).
In the digital signal processor DSP-B, the set transmission frame is formed by the frame data received by the digital signal processor DSP-A or the outside (microcomputer), and the timing clock indicated by the broken line in FIG. The transmission timing is taken from the circuit 9 in accordance with the Ta signal.
Thereby, the timing of the frame transmitted from the base station becomes constant.

  Another embodiment of the inter-channel synchronization method in the digital radio base station according to the present invention will be described. In this case, for example, the relationship between one of the control channel frames at the base station and the other one of the communication channel frames is as shown in FIG. The timing of the control channel in the base station and the transmission channel of the call channel must be the same. Alternatively, the timing is fixed. Therefore, the transmission timing of the control channel and the timing of the transmission frame of the speech channel are synchronized by the timing signal Ta in FIG.

A reference timing clock is output from the controller for the control channel, and the other controller inputs the timing clock.
The Ta signal in FIG. 1 is used as a timing clock output from the control channel controller. Alternatively, the signal at the timing of Ta in FIG. 5 is made to correspond as a signal from the control channel controller, and the transmission timings of the control channel and the communication channel are matched and controlled.
Thereby, the timing shift of the frame (modulated wave) transmitted from the control channel and the communication channel is kept constant.

It is a block diagram with which it uses for description of the synchronization method between channels in the digital radio base station concerning embodiment of this invention. It is a schematic diagram which shows the synchronization between channels in the digital radio base station concerning embodiment of this invention concerning embodiment of this invention. It is a flowchart which shows the process for the synchronization between channels in the digital radio base station concerning embodiment of this invention. It is a flowchart which shows the other process for the synchronization between channels in the digital radio base station concerning embodiment of this invention. It is a schematic diagram which shows the synchronization between channels in the digital radio base station concerning the other form of implementation of this invention concerning embodiment of this invention. It is a block diagram with which it uses for description of the synchronization method between the channels in the conventional digital radio base station. It is another block diagram with which it uses for description of the synchronization method between the channels in the conventional digital radio base station.

Explanation of symbols

1 and 6 Amplifier 2 A / D converter DSP-A and DSP-B Digital signal processor 4 Codec 5 Switch circuit 7 VCO

Claims (4)

  Configure a reception frame based on the received signal received by the digital signal processor on the reception side in the digital radio base station, configure a transmission frame based on the reception frame in the digital signal processor on the transmission side in the digital radio base station, A transmission timing signal is generated at a predetermined timing from the start timing of the first frame of the reception frame or after the reception frame is configured, and when the transmission timing signal is received, the transmission frame is transmitted from the digital signal processor on the transmission side. An inter-channel synchronization method in a digital radio base station characterized by the above.    2. The inter-channel synchronization method in a digital radio base station according to claim 1, wherein the transmission frame is transmitted by an external input signal separately from the reception frame.     3. The inter-channel synchronization method in a digital radio base station according to claim 1, further comprising means for controlling transmission timing of a control channel and a speech channel. Configure the reception frame based on the received signal received by the digital signal processor on the receiving side in the digital radio base station, configure the transmission frame based on the received frame in the digital signal processor on the transmission side in the digital radio base station, Generate a transmission timing signal at a predetermined time from the start timing of the first frame of the reception frame or after the reception frame is configured, and send the transmission frame from the digital signal processor on the transmission side when receiving the transmission timing signal An inter-channel synchronization program in a digital radio base station programmed to be computer-controllable.

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