JPH04156749A - Loop back control system - Google Patents

Abstract

PURPOSE:To transmit a loop back control signal via a simple circuitry by providing a conversion rate control part inverting the transmission speed of a subframe of a compound frame shape on the transmission side in a subframe unit and a conversion signal decision part deciding the inverted subframe on the reception side. CONSTITUTION:In the case of the loop back control from a station A to a station B, the output signal of a conversion rate control part 4 for the station A is inverted by the loop back control signal from a terminal 5. When this inverted signal is received at the station B, a conversion signal decision part 15 decides the conversion rate of the received signal as a normal inversion, and the loop back of a digital signal is performed by controlling a relay 10 for loop back. The control of a drawn circuit from the station B to the station A is the same. Thus, the loop back signal can be transmitted by a simple circuitry.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a loopback control system, and in particular,
The present invention relates to a loopback control method in which a digital signal having a composite frame format that is transmitted to a station is looped back from a station B to a station A using a control signal from the A station.

[Conventional technology]

Conventionally, in this type of loopback control method, the loopback control signal sent from station A to station B is multiplexed by superimposing a signal different from the frequency of the main digital signal, or by interrupting a time slot on the time axis. It was transmitted to station B using a multiplexing method. Here, as shown in FIG. 3(a), the main digital signal is, for example, a subframe 1.3 composed of a digital signal having a certain transmission speed.
This is a composite frame signal in which one superframe is composed of subframes 2 and 4, which are composed of digital signals having different transmission speeds from those mentioned above, and the main digital signal has the same composite frame format in uplink and downlink. is being transmitted.

[Problem to be solved by the invention]

In this conventional loopback control method, it is necessary to multiplex the loopback control signal onto the main digital signal in time slots on the frequency axis or time axis, so a multiplexing circuit for superimposing the loopback signal and a separation circuit are required. However, there is a disadvantage that the signal spectrum becomes wider than the spectrum of the main digital signal due to multiplexing.

[Means to solve the problem]

The loopback control method of the present invention is characterized in that when converting from the input main digital signal speed to the signal speed of the wireless section,
In a loopback control method used in a digital wireless system that transmits a composite frame signal in which the transmission rate conversion rate is periodically changed for each of multiple subframes within a superframe, the transmitting side of the digital wireless system The digital wireless system has a first means for dividing the subframe into at least two groups and transmitting a composite frame signal in which the different transmission rate conversion rates of each group are converted to the transmission rate conversion rates of other groups. The receiving side has second means for receiving the composite frame signal converted by the first means and determining the polarity of the transmission rate conversion rate of each subframe group, and a loop is formed based on the determination result of the second means. Controls the back relay.

〔Example〕

Next, the present invention will be explained with reference to the drawings.

FIG. 1 is a block diagram of one embodiment of the present invention.

In the embodiment shown in FIG. 1, if station A is the control side station and station B is the loopback side station, the sending side of the A station is the main digital signal input terminal 1. Loopback relay for A station 2. 3. Transmission signal speed conversion circuit that converts the transmission speed in units of subframes within a superframe. A conversion rate control section 4 that controls the transmission signal speed conversion circuit 3 and performs speed switching control in subframe units. It consists of a terminal 5 for loopback signal input. On the other hand, on the receiving side of the B station, which receives the sending side of the A station, a reception signal rate conversion circuit 14 decodes the main digital signal in units of subframes, and this subframe 1
, 3 and subframes 2.4, and a digital signal output terminal 16 of a loopback relay 101 on the B station side. If the above-mentioned line is a downlink, the digital signal input terminal 9 constitutes an uplink from station B to station A. Relay 10, transmission signal conversion circuit 11. Conversion rate control section 12° Reception signal speed conversion circuit 6. Converted signal determination unit 7. Relay 2. The digital signal output terminal 8 also has a similar configuration.

Next, the operation of this embodiment will be explained. In FIG. 1, when performing loopback control from station A to station B, the output signal of conversion rate control section 4 of station A is inverted by a loopback control signal from terminal 5. In other words, at "1 level" of the speed conversion rate control signal A shown in FIG. 3(b), subframe 1
, 3 is set, and the transmission speeds of subframes 2 and 4 are set at the '0'' level. By inverting to the speed conversion rate control signal B,
The transmission speed of subframes 2 and 4 is switched to the transmission speed of subframes 2 and 4. Further, the transmission speed of subframes 2 and 4 is switched to the transmission of subframes 1 and 3.

When this inverted signal is received at station B, the converted signal determination unit 1
5, it is determined that the conversion rate of the received signal is inverted from the normal one, and the digital signal is looped back by controlling the loopback relay 10. The same applies to uplink control from station B to station A. Here, if we focus on one superframe, which is a composite frame, subframe 1
The total number of bits in one superframe, which is the sum of the total number of bits determined by the transmission speed of subframes 1 and 3 and the total number of bits determined by the transmission speed of subframes 2 and 4, is the sum of the total number of bits determined by the transmission speed of subframes 1 and 3 and subframes 2 and 4. It does not change even if I change the transmission speed.

Next, the operation of the converted signal determining sections 7 and 15 will be explained using the block diagram shown in FIG. The received digital signal is now input to a frame synchronization determination circuit 21 from an input terminal 20, and it is determined whether or not frame synchronization is established. At this time,
For example, it is determined by checking bit by bit that the signal format from station A is reversed from the regular signal format in subframes 1, 3 and 2, 4 and synchronization cannot be achieved. Since this determination time spans approximately 2.5 subframes, the time constant circuit 22 controls the conversion rate control circuit 23 after the elapse of this fixed determination time to send a conversion rate control signal to the frame synchronization determination circuit 21 and invert it. ,
Frame synchronization can be achieved. Also, at this time, the output signal of the time constant circuit 22 is sent to the relay control output 24 to control the loopback relay 10 (or 2) as a determination signal.

Note that since this method is used for testing, etc., frame synchronization may be temporarily lost during loopback control, but this does not affect line operation. Also, when the conversion rate of the loopback signal from station B is inverted as a reply signal from station B which has received remote loopback control, this inversion information is sent to station A and recognized as the loopback control reply signal. Therefore, it can also be used as a response signal for the loopback method of this embodiment.

〔Effect of the invention〕

As explained above, the present invention includes a conversion rate control unit that inverts the transmission rate of subframes in a composite frame format on a subframe basis on a transmitting side, and a conversion signal determination unit that determines the inverted subframes on a receiving side. By providing the above section, there is an effect that the loopback control signal can be transmitted with a very simple circuit configuration. Furthermore, there is an effect that a loopback signal of new information can be sent without changing the total number of bits within one superframe.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a block diagram of a converted signal determining section which is the main part of this embodiment, and FIG.
)+ (b) and (c) are signal formats for explaining this embodiment and the conventional example. 1.9...Digital signal input terminal, 2.10...Relay, 3.11...Transmission speed conversion circuit, 4,12...
・Conversion rate control unit, 5.13...terminal, 8,14...
Received signal speed conversion circuit, 7, 15... Converted signal determination unit, 8.16... Digital signal output end, 20... Received signal input end, 21... Frame synchronization determination circuit, 22
... time constant circuit, 23 ... conversion rate control circuit, 24.
...Relay control output terminal.

Claims (1)

[Claims] 1. A composite frame in which the transmission rate conversion rate is periodically changed for each of a plurality of subframes within one superframe when converting the input main digital signal rate to the signal rate in the wireless section. In a loopback control method used in a digital wireless system for transmitting signals, the transmitting side of the digital wireless system divides a plurality of subframes into at least two groups, and adjusts the different transmission rate conversion rates of each group to the other groups. the receiving side of the digital radio system receives the converted composite frame signal of the first means and transmits the composite frame signal converted to a transmission rate conversion rate of A loopback control system comprising second means for determining the polarity of a transmission rate conversion rate, and controlling a loopback relay based on the determination result of the second means. 2. The second means includes a frame synchronization determination circuit that determines the transmission speed conversion rate of each subframe of at least two groups, a time constant circuit that suspends the determination time of the frame synchronization determination circuit, and the frame 2. The loopback control system according to claim 1, further comprising a conversion rate control circuit that inverts the transmission rate conversion rates of the two groups when the synchronization determination circuit determines non-synchronization.