HU183363B - Circuit arrangement for the quality control of the regenerator chains transmitting digital signals, first of all, of chains of the radio relays - Google Patents

Abstract

The present invention relates to a circuit arrangement for controlling the quality of regenerator chains that transmit digital signals, particularly radio relay chains. It is an object of the present invention that the signal output from the repeater stations is signal quality indicator controlled by a digital distortion circuit directly or via a clock synchronization circuit controlled circuitry coupled to the signal transmission link. According to the invention, the solution is that the signal output of the repeater station is connected to the signal transmission link via a sampling circuit, a signal quality indicator controlled by a digital distortion circuit. The advantage of the switching arrangement is that it can transmit the alarm information through the regenerating repetition chain to the end of the chain of any length so that the chain automatically returns to its original correct state when the error rate is exceeded. -1-

Description

The present invention relates to a circuit arrangement for controlling the quality of regenerator circuits, in particular radio relay circuits, transmitting digital signals.

On communications lines, it is often necessary, for attenuation of the transmission medium or for other reasons, to place amplifying devices at certain distances along the transmission path, so-called repeater stations, which receive, amplify, and transmit at a higher level to the next repeater station. When transmitting digital signals at repeater stations, it is possible for the signals to be regenerated, so that the output signal of such a regenerator is virtually independent of the distortion of the signal in the preceding section due to noise, crosstalk, distortion or other effects. Such regenerative repeater stations are used almost exclusively by digital cable and radio relay systems.

The most important quality characteristic of a system for transmitting digital signals is the error rate - the relative number of signals received incorrectly. The quality standards of such systems are also primarily concerned with the error rate: if the error rate exceeds the value that is practically acceptable, the transmission system can no longer be used, instead the information must be transmitted to a backup system or backup and an alarm signaled to the operating staff.

The acceptable worst case error rate is 10 ~ ³ l CT ⁶ .

In order for the equipment to perform the necessary switching and alarming measures, the connection error rate must first be measured continuously. Several methods are known for continuously measuring the error rate during operation. Some of them assume that some of the information transmitted is already known; others require a signaling channel independent of the main information path (usually at much lower speeds), while others use error signal coding in the signal stream to be transmitted; finally, there are continuous error rate monitoring methods that monitor the corresponding parameters of the bits of the transmitted signal and from this, filter the inference of the error rate. The latter method is in many respects more favorable than the others: the transmitted stream does not have to have a known bit group, so such a system has the so-called "transparency" property; does not require a signaling channel; there is no need for fault code encoding circuits which, even with advanced integrated circuit technology, are very complex and relatively slow to operate. Therefore, they are widely used in both wired and wireless technology. In these methods, a redundant property of a signal is investigated for bit error detection, and a deviation from the rule is evaluated as a bit error. A circuit monitoring such deviation from such regularity will hereinafter be referred to as a signal quality indicator. Such observable properties upon which the known bit error monitoring methods are based (among others) are: deviation from the bipolar rule in bipolar transmission used in wired systems; violation of the biphasic rule for high-speed bitstream and bitstream, or so-called CMI (coded mark inversion) transmission in FSK and ASK systems; Transmission of NRZ signals in the middle of the bit-time. The latter method is particularly advantageous for radio transmission. The point is that a narrow time slot is selected in the middle of each bit time, say 20% of the bit time.

The fault monitoring circuit examines whether the transition of the received non-regenerated signal is within this time slot. If so, it is most likely related to a bit error. Therefore, transitions at such a defective location are counted; these numbers have been found to be very close to the number of bit errors, so the switching and alarm circuits are operated on the basis of these counters.

The disadvantages of the above system, as well as those of the other systems described, are summarized as follows: They work well in a regenerator whose input signal contains faulty bits (due to noise or circuit failure) and can generate a local alarm or initiate a switch this generator is also a standby switching station. However, if there is no supervisory personnel or backup switching equipment at this regenerator station, but at a remote location, the following occurs: At the same time, due to the increased error rate, the monitoring circuit generates an alarm signal, the regenerator regenerates the received (defective) signal. Once again, the regenerated signal has all the properties that a monitoring bit described by the monitoring circuit evaluates to be defective: its transitions are in the right place, it does not violate the bipolar or biphasic rule, and so on. Thus, the next repeater station evaluates this as correct and does not, of course, generate an alarm signal; that is, the monitoring or switching station is not aware of a fault in the remote regenerator. The trivial solution is to report this through a separate signal channel, but this is not always available and often too slow.

The present invention avoids this difficulty by providing a circuit arrangement for transmitting this alarm information to the end of a chain of any length through a regenerative repeat chain such that the chain automatically returns to its original correct state when the error rate is exceeded. The nature of the transmitted signal - its spectrum or other properties - virtually remains unchanged when transmitting alarm information.

The point of the present invention is that the fault monitoring circuit, at the same time as generating the alarm signal after detecting the "bad condition", performs another intervention. This modifies the output signal of the regenerator in the sense that it is considered by the next regenerator to be faulty. Thus, the alarm is generated here at the same time as the intervention described above occurs; thus, the alarm information was transmitted by a regenerator and the latter was prepared to transmit the alarm. This process is performed sequentially in all regenerators until eventually the alarm information is sent to the backup switching station or monitoring station, where the backup switching takes place or the monitoring staff is notified of the alarm. The intervention itself is the proper distortion of the regenerated signal, where this distortion is digital: changing the clock frequency appropriately (slightly) changes the speed of the signal, performs a negation at the appropriate places, multiplies the output signal with another signal, , inverting signal impulses in algebraic sense, etc. The circuit performing such operations will be referred to as a digital distortion circuit.

The present invention relates to a circuit arrangement for controlling the quality of regenerator circuits transmitting digital signals. The signal output of the repeat station receivers is signal quality indicator-21

It is coupled to a signal transmission link directly or via a clock synchronization circuit controlled by a digital distortion circuit controlled by 183,363 torrents.

The circuit arrangement of the present invention is where the signal output of the repeat station receivers is coupled to a signal transmitting link through a digital distortion circuit controlled by a sampling circuit with a signal quality indicator.

1 shows an embodiment of a circuit arrangement according to the invention.

Fig. 2 is a circuit arrangement according to the present invention in which the digital distortion circuit performs a stepwise inversion of the output (regenerated) signal.

FIG. 3 is an embodiment of the embodiment of FIG. 1, wherein the digital distortion circuit is implemented in the form of a clock changing frequency clock circuit.

The circuit arrangement of FIG. 4 is the embodiment of FIG. 3, wherein the digital distortion circuit is implemented in the form of an intermittently inverting circuit of the output of the clock synchronization circuit.

Figure 5 is an embodiment of the circuit arrangement of Figure 2.

In the circuit arrangement of Fig. 1, a clock synchronization circuit 5 and a JMI signal quality indicator are connected to the receiver V in addition to the sampling circuit 11. The output of the JMI signal quality indicator is, on the one hand, the alarm signal output 9 and, on the other hand, is connected to the digital distortion circuit DT, the output of which is connected to the clock synchronization circuit 5. The output of the clock synchronization circuit 5 is connected to the sampling circuit 11. The output of the All sampling circuit is also the output of the signal to be transmitted.

2, the output of the sampling circuit 11 is connected to a digital distortion circuit DT and the output of the digital distortion circuit is the signal output to be transmitted. Here again, the output of the JMI signal quality indicator is the 9 alarm signal outputs. An embodiment of the circuit arrangement of FIG. A clock synchronization circuit 5 and a transition monitoring circuit 6 are connected to the output of the receiver V consisting of mixer 1, mid frequency amplifier 2, local oscillator 3 and demodulator 4. The JMI signal quality indicator following the clock synchronization circuit 5 consists of a time slot assignment 7, a transition monitoring circuit 6 and a counter 8. The clock generator 13 and the clock switch 12 are mounted as digital distortion circuits DT of FIG. 1 and are connected to the output of the clock synchronization circuit 5.

The clock generator 13 may be an independent freewheeling oscillator; in other cases, however, it may have a frequency rigidly related to the frequency of the clock synchronization circuit, e.g., m / n times its m and n, e.g. 10-20% different integers. This is particularly advantageous if the signal of the clock synchronization circuit 5 is obtained by dividing the frequency of a larger lying oscillator. The output of the time slot selector 7 is connected to the transition monitoring circuit 6. The counter 8 is connected to the output of the clock synchronization circuit 5. The output of the counter 8 is the alarm output 9 of the switching arrangement and the connection point of the switch controller 10. The control point of the clock switch 12 is connected to the switch controller 10. The output of demodulator 4 is also directly connected to the sampling circuit 11. All sampling circuits are connected to the 12 clock switch. A modulator 14 is connected to the output of the sampling circuit 11 and is connected to a transmitter generator 15. The operation of the circuit arrangement of Figure 3 is as follows:

At the output of the receiver consisting of mixer 1, mid frequency amplifier 2, local oscillator 3 and demodulator 4, an unregulated received signal is displayed. The clock synchronization circuit 5 generates a clock signal which is synchronized with the received signal.

The received signal is also applied to the input of the transition monitoring circuit 6, which monitors transitions in the narrow time slots designated by the slot synchronizer 5 controlled by the clock synchronizer 5 and, each time a transition is detected, emits a pulse to the counter 8 after the set time has elapsed; however, if this threshold is reached before this time (for example, it counts more than 10-30 pulses), it will output the alarm signal at alarm output 9. The transition monitoring circuit 6, the time slot assignment 7 and the counter 8 together form the JMI signal quality indicator known per se. However, this signal is also applied to the switch controller input 10. On the other hand, the output signal of the demodulator 4 is applied to the input of a sampling circuit which essentially performs the signal regeneration. Sampling is always performed at one of the edges of the clock signal 12, such as a rising edge, which has an input of the clock synchronization circuit 5 at one of its inputs and a separate clock generator 13 at the other input. The clock generator 13 has a frequency such that it is out of the synchronization band of the clock synchronization circuit 5 (or the clock synchronization circuit of the next repeater station). The switch controller 10 controls the clock switch 12 so that the signal of the clock synchronization circuit 5 is output to the latter if the connection is good and no signal is output at the alarm output 9; however, when this alarm signal is displayed, the clock generator 13 will be displayed at the output of the 12-hour switch. Thus, the output signal of the sampling circuit 11, which is transmitted via the modulator 14 fed by transmitter generator 15 to the next repeater station, will be synchronized with the demodulator 4 signal (i.e. regeneration of the received signal) with good connection and clock clock signal 13 with incorrect connection. will be in sync. The clock synchronization circuit of the next repeater station will not synchronize with this signal, so an alarm signal will appear on the alarm branch there, initiating a repeat of the process described above.

A slightly modified version of the circuit arrangement shown in Figure 3 is shown in Figure 4. Here, the clock generator 13 is missing, but instead the clock synchronizer signal 5 passes through the controlled binary inverter 17 to the all sampling circuit. The control input of this is supplied by the signal of the rectangle generator 16, at which time the input of the sampler 11 receives a clock in the correct phase or inverted. The frequency of the rectangle generator 16 is preferably one tenth of the bit frequency or less.

Turning the square generator 16 on or off is done by the switch controller 10, if the connection is good (no alarm signal), the square generator 16 is turned off (the clock phase is correct); if the connection fails, the switch controller 10 turns on the rectangle generator 16 (in which case the clock phase is periodically 180 3).

-3183 363 kai changes). As a result, transitions of the regenerated signal, and thus transmitted to the next repeater station, occur at an irregular location, thereby achieving the desired effect. The embodiment shown in Figure 5 may be used in a biphasic or CMI (Coded Mark Inversion) coding connection. Here, the goodness of the connection is monitored by the injury indicator 18 such that there are three consecutive half-bits of equal value. (In this example, the damage indicator 18 is a JMI signal quality indicator.)

When an alarm is triggered, switch controller 10 switches on pulse generator 19, which produces pulses of half-bit length; these drive a controlled binary inverter 17 which thus periodically inverts one half-bit. This will initiate a similar process at the next repeat station. In this example, the controlled binary inverter 17 with the pulse generator 19 forms the digital distortion circuit DT according to the invention.

Another embodiment of the invention is advantageously used in bipolar (e.g., AMI Alternate Mark Inversion encoding or HDB High Density Bipolar encoding) systems. Its structure is exactly the same as that of Figure 5, but now 17 represents a controlled pulse inverting circuit which reverses the sign of a positive or negative pulse instead of a controlled binary inverting circuit, whereas the injury indicator 18 now monitors incorrectly consecutive pulses of the same polarity.

Claims (2)

Patent claims 1. A circuit arrangement for controlling the quality of regenerator circuits transmitting digital signals, wherein each of the regenerators of the regene5 burst circuits is located at the repeater stations of the connection and is connected to the receiver of the repeater station. ) signal output, preferably as a repeater station, is coupled to a signal transmission link (15) controlled by a signal quality indicator (JMI) directly controlled by a digital distortion circuit (DT) or via a clock synchronization circuit (5) (Fig. 1). 2. A circuit arrangement for controlling the quality of regenerator circuits transmitting digital signals, wherein each regenerator of the regenerator chains is located at the repeater stations of the link and the repeater station And include a clock synchronization circuit, a sampling circuit and a signal / quality indicator, characterized in that the signal output of the repeat station receivers (V), preferably as a repeater station, is provided by a sampling circuit (11), It is coupled to a signal transmission link via a digital distortion circuit (DT) controlled by 25 signal quality indicators (JMI) (Figure 2).