CS262205B1 - Wiring to identify and locate errors in the digital signal receiver - Google Patents

Abstract

The invention relates to a circuit for identifying and locating errors in a digital signal receiver, which contains regenerative circuits and is intended in particular for receivers with adaptive quantized feedback. The error detectors known so far in digital signal receivers operate on the principle of monitoring code algorithm violations. The main disadvantage of these detectors is that their efficiency is proportional to the redundancy of the linear code, but decreases in the case of burst errors. Due to the relatively small redundancy of the linear codes used, the known error detectors are not able to locate errors accurately and, in most cases, they cannot even identify them accurately. This makes it practically impossible to use the known error detectors in adaptation instruction processors in digital signal receivers with adaptive quantized feedback, where it is necessary to identify and locate errors as accurately as possible, with regard to the optimal generation of adaptation instructions. The above disadvantages are significantly limited by the circuit according to the invention, the essence of which lies in the fact that the state output of the regenerative circuits is connected to the information input of the accumulation element, the output of which is connected to the signal input of the analytical block and the code output of the regenerative circuits is connected to the code input of the evaluation element, while the elimination output of the evaluation element is connected to the elimination input of the accumulation element and each of the outputs of the analytical block is connected to at least one of the conditional inputs of the evaluation element. The main advantages of the circuit according to the invention lie in the fact that its function is independent of the redundancy of the line code and that it can work even with an uncorrelated signal, while, with the correct design of the digital signal receiver in which the circuit according to the invention is used, its operation is almost not influenced by the error density in the signal. The attached Fig. 1 shows a block diagram of an example of a circuit according to the invention, and Fig. 2 shows the time courses of signals in some important places of the circuit according to the invention, while Fig.

Description

The invention relates to a circuit for identifying and locating errors in a digital signal receiver which comprises regenerative circuits and is particularly intended for adaptive quantized feedback receivers.

Previously known error detectors in digital signal receivers operate on the principle of guarding the code algorithm violation.

The main disadvantage of these detectors is that their efficiency is proportional to the redundancy of the LinRo code, but decreases in the case of burst errors. Due to the relatively low redundancy of the used line codes, known error detectors are unable to accurately locate errors and usually cannot accurately identify them. This practically makes it impossible to use known error detectors in adaptive instruction processors in adaptive quantized feedback digital signal receivers, where errors need to be identified and located as accurately as possible for optimum generation of adaptation instructions.

These drawbacks are greatly reduced by the circuitry of the present invention, the nature of which is that the state output of the regenerative packs is coupled to the information input of the cumulative member whose output is associated with the signal input of the analysis block and the code output of the regenerative packs. the circuitry is coupled to the evaluation member's code input, wherein the evaluation member's elimination output is coupled to the cumulative member elimination input, and each of the analysis block outputs is coupled to at least one of the evaluation member's condition inputs.

The main advantages of the circuitry according to the invention are that the function is independent of the link code redundancy and that it can work even with an uncorrelated signal and that, with the correct design of the digital signal receiver in which the circuitry is used, almost affected by signal error density.

1 is a block diagram showing an exemplary circuit according to the invention, and FIG. 2 shows the waveforms of signals at some significant circuit locations according to the invention, and FIG.

Fig. 2a shows the course of a lone imI pulse at the input of a non-plotted detector in regenerative circuits,

2b - a pulse is displayed on the elimination output of the evaluator after correctly detecting the transmitted positive pulse,

Fig. 2c shows the voltage at the output of ku262205 of the mulching element at the input signals shown in Figs. 2a, 2-b;

2d - the signal at the elimination output of the evaluating element, divided into two pulses after correctly detecting the transmitted positive pulse, is shown,

Fig. 2e shows the voltage at the output of the cumulative element at the input signals shown in Figs. 2a, 2d;

2f - shows the course of a lone pulse disturbed by noise (shaded part), at the detector input in regenerative circuits,

2g - the waveform of the pulse on the elimination output of the evaluator is shown after it has been detected. erroneously detected currentless location and not positive impulse,

Fig. 2h shows the voltage at the output of the cumulative member at the input signals shown in Figs. 2f, 2-g.

The arrows in Figs. 2a, 2f indicate the detector decision moments in the regenerative circuits, the arrows in Figs. 2c, 2e, 2h indicate the decision points of the analysis block location. The symbols T1, T2, T3, T4 indicate the localization decision moments, significant in terms of detecting the isolated pulses shown in Figures 2a, 2f.

The circuitry of the invention comprises regenerative circuits 1, a cumulative member 7, an analysis block 11, an evaluation member 15, and a quantized coupling block 20. The code output 5 of the regenerative circuits 1 is coupled to the code input 16 of the evaluation member 15. The status output 6 of the regenerative circuits 1 is. connected to the information input 9 ^ cumulation whom you member 7, a feedback output 3 regenerative circuits one is connected to the signal input 21 of the block 20 the quantized ^bond! and a signal output is connected to the feedback input 4 of the generators / circuits 1. 23 of block 20 of quantized binding.

Elimination output. 18, the evaluation element 15 is coupled to the elimination input 8 of the accumulation element 7, the output of which is connected to the signal input 12 of the analysis block 11. The clock input 13 of the analysis block 11 is. the clock signal source 10 is connected. Each of the nine outputs. 14 of the analysis block 11 is connected to one of the nine condition inputs 17 of the evaluation member 15. Each of the two modification outputs 19 of the evaluation member 15 'is connected to one of the two adaptation inputs 22 of the quantized coupling block 20.

Six threshold detectors 24 are connected to the signal input 12 of the analytical block 11, each of them being the signal input 25 of the threshold detector 24. The clock inputs 26 of the threshold detectors 24 are connected to the clock input 13 of the analytical block 11. , always by the clockwise input 29 of the shift register 27.

Signal input 28 of first shift register 27 is connected to output of first threshold detector 24, signal input 28 of second shift register 27 is connected to output of third threshold detector 24, signal input 28 of third shift register 27 is connected to output of fourth threshold detector 24 - and the signal input 28 of the fourth shift register 27 is connected to the output of the fifth threshold detector 24.

The first output 14 of the analysis block 11 is connected to the output of the first shift register 27 and the second output 14 of the analysis block 11 is connected to the output of the second threshold detector 24. The third output 14 of the analysis block 11 is connected to the third stage output of the second shift register 27. The fifth output 14 of the analysis block 11 is connected to the second stage output of the third shift register 27, the output of which the first stage is connected to the sixth output 14 of the analysis block 11.

The seventh output 14 of the analysis block 11 is connected to the output of the fourth shift register 27. The eighth output 14 of the analysis block 11 is connected to the output of the fifth threshold detector 24 and the ninth output 14 of the analysis block 11 is associated with the output of the sixth threshold detector 24. The first two of the nine condition inputs 17 of the evaluation member 15 are coupled to the two inputs of the first condition member 30, the output of which is coupled to the first m-de-isolation output 19 of the evaluation member. 15 and a third control input. 35 of the source of the elimination signals 34, the output of which is coupled to the elimination output 18 of the evaluation member 15.

To each of the remaining seven condition inputs 17 of the evaluation member 15 is connected one of the seven inputs of the second condition member 39, the output of which is connected both to the second modification output 19 of the evaluation member 15 and to the second control input 35 of the source of elimination signals. The first control-input 35 of the elimination signal source 34 is connected to the code input 1.6 of the evaluation member 15. The sampling input 36 of the elimination signal source 34 is connected to the output of the accumulation member 7.

The second condenser member 30 consists of a gate 31, six resistors 32a and a conditional threshold detector 33. The second terminals of the resistors 32 are connected to each other and are connected to an input of the conditional threshold detector 33 whose output is coupled to the output of the conditional member. 30. The first terminal of the sixth resistors 32 is connected to the output of a two-input gate 31 whose two inputs are connected to the sixth and seventh

Each of the remaining five inputs of the conditional member 30 is coupled to the first terminal of one of the other five resistors 32. i When a attenuated and distorted positive pulse is coming from the line, it enters the correction signal (not shown) via signal input 2 of the regenerative circuits. · Amplifiers where it is amplified and corrected, see Figure 2a. Further, this impulse proceeds both in the regenerative circuits 1 to an undetected detector, which detects the type of transmitted signal element, but at the same time turns through the status output 6 of the regenerative circuits 1, which is led eg from the detector input to the information input 0 of the accumulation element 7.

In the cumulative member 7, the signals arriving at the information input 9 of the cumulative member 7 and the elimination input 8 of the cumulative member 7 are subtracted or added up, depending on the polarity with which the signals are generated in the source 34 of the elimination signals. member. It has approximately the frequency response of the integrator, ie it emphasizes lower frequencies before higher ones.

However, in order to achieve the maximum signal-to-noise ratio at the signal input 12 of the analysis block 11, it is more convenient in practice to reduce the integrator gain at low frequencies and completely suppress component transfer at the lowest frequencies. The detector in the regenerative circuits 1 gives information about the type of signal element it has detected through the first control input 35 of the source of the elimination signals 34, which generates an elimination pulse, see Fig. 2b, and sends it to the elimination input 8 of the accumulation member 7.

The effect of the elimination pulse is such that, in the case of a correctly detected signal element and without the presence of noise, there is zero voltage at the decision points of the location of T1 and T2 at the output of the accumulation member 7, see Fig. 2c. An elimination pulse that suppresses the effect of a correctly detected pulse in the accumulation member 7 must be generated with high accuracy of time position in the source of the elimination signals, since any deviation would cause signal distortion at the localization decision time Ti which is within the duration of the elimination. impulse.

A more advantageous solution is to divide this elimination pulse into two pulses of different amplitude, or to separate them by a gap in which said localization decision point is located. This can increase the immunity of the wiring to the jitter clock pulses of the localization decision moments, see Figures 2d, 2e.

if the detector in the regenerative circuits 1 has not detected a positive pulse but has detected an erroneous current spot, the accumulation of the positive pulse voltage will not be correctly eliminated in the accumulation element 7, and

At the decision times of the location T3, T1 will not be zero at the output of the cumulative member 7.

The simplest way of detecting a false decision is by detecting that a predetermined voltage level has been exceeded by one threshold detector 24 at one of the decision points of the Ts or Ti location. However, a more accurate and plausible result will give an evaluation of the signal at the output of the cumulative member 7 at both decision points T1, T1. if the voltage at the output of the cumulative member 7 exceeds the decision level of the first threshold detector 24 at the decision location location Ts, a pulse is written to the connected first shift register 27.

At the next decision point T1, the voltage at the output of the cumulative member 7 exceeds the decision level of the second threshold detector 24, and a non-zero voltage appears at its output, which is coupled to the two inputs of the first conditional member. 30.

The conditional member 30 generally operates to output a logical one at its output when the number of logical ones at its inputs has reached or exceeded a specified threshold. If this limit equals 100%, the conditional member 30 may be realized by a circuit having the function of a logic product, as is true for the first conditional member 30, see Fig. 1.

In order to eliminate the saturation of the cumulative member 7 by the energy of the detected pulse, which would cause continuous evaluation of the false signal detection, after the bending criterion is evaluated, information is output from the first conditional member 30 to the third control input 35 of the elimination signal source 34 to generate an elimination pulse. This procedure is graphically documented in Figs. 2f, 2g, 2h.

It is possible that by the above described method, the false detection in the regenerative circuits 1 is not found with sufficient credibility. In such a case, it is advantageous to analyze the signal over a longer period of time with reduced signal-to-noise ratio. In the circuit according to this embodiment, four localization decision points are analyzed.

The effect of noise on the correct decision can be further reduced by equipping the conditional member 30 with additional inputs which examine the signal at the output of the cumulative member 7 at a given relative delay still at the threshold level detector 24 set for a lower noise level. The collection of information in the second conditional member 30 is resolved by a resistive network based on the principle of an analog summator whose output voltage is converted to logical levels in the conditional threshold detector 33.

The accuracy of the error criterion evaluation can be further increased by analyzing the signals characterized by the same delay at their localization decision point by evaluating the logic sum function, as in the second conditional term 30 is solved with the last two conditional inputs 17 of the evaluating term 15 The saturation of the cumulative member 7 is again removed by triggering the generation of an elimination pulse with energy equal to the energy that comes from the output of the second conditioner 3H to the second control input 35 of the source of elimination signals. in the cumulative member 7 was from the useful pulse until the second condition member 30 transmitted its signal.

The wiring operation described so far was based on the assumption that the error state is signaled by a voltage greater than the threshold value. However, the opposite states also occur. It is then advantageous to connect an inverter behind the output of the respective threshold detector 24 and / or to the output of the respective shift register 27.

Upon completion of the elimination. In the process, the error voltage given by the integrated noise, which is represented by the shaded area in FIG. 2f, remains at the output of the cumulative member 7.

It may also be the case that the evaluation member 15 is unable to unambiguously assess the existing situation, for example because of the large accumulated error voltage. In such a condition, it is advantageous to reset the accumulation member 7. The reset pulse is a pulse of, for example, a rectangular shape that can be generated from the moment the reset command is generated to the next localization decision point. Its amplitude is determined by the voltage at the output of the cumulative member 7 at the time of evaluating the zero criterion that is applied to the sampling input 3S of the source of the elimination signals 34. The zero pulse is applied to the accumulation member 7 in the same manner as the other elimination pulses.

In an adaptive quantized feedback digital signal receiver, the effect of an erroneous compensation pulse in the accumulation member 7 is suppressed by an elimination pulse that is again generated in the source of the elimination signals 34 based on a signal from one of the condition members 30.

The purpose of this elimination pulse is to suppress the effect of the error compensating pulse until the error is identified and scaled because the rest of the error compensating pulse is suppressed already within the quantized coupling block 20 by modifying the compensation signal caused by the adaptation instruction sent to an adaptation input 22. block 20 of the quantized coupling from the output of that condition member 30 that also commanded the source of the elimination signals 34 to generate the respective elimination pulse.

As the source of the elimination signals 34, one source can be used, eg a function generator controlled by several control variables, or it can be realized by several more or less independent independent elimination pulse generators whose signals can be added together in the source 34, or up to the accumulation element 7.

In order to maintain its function, the source of the elimination signals 34 has non-drawn logic circuits connected by their inputs to the control inputs 35 of the source of the elimination signals 34 which evaluate the incoming control signals so that the source 34 eliminates the correct elimination pulses or command to reset cumulative term 7.

A further advantage of the circuitry according to the invention is that the signal from the output of the conditional elements can also be used for other functions, for example to correct a faulty signal element before sending it to another member of the communication system.

Claims (2)

A circuit for identifying and locating cnyb in a digital signal receiver comprising regenerative circuits, characterized in that the status output (6) of the regenerative circuits (1) is coupled to the information input (9) of the accumulation member (7), the output of which is connected to the signal input (12) of the analysis block (11) and the code output (5) of the regenerative circuits (1) is connected to the code input (16) of the evaluation member (15), the elimination output (18) of the evaluation member (15) connected to the elimination input 8) the cumulative member (7) and each of the outputs (14) of the analysis block (11) is connected to at least one of BACKGROUND TO the condition inputs (17) of the evaluating member (15) .2. Connected according to point I, characterized in that at least one threshold detector (24) is connected to the signal input (12) of the analysis block (11), its output connected to the first of the outputs (14) of the analysis block (11) and / or at least one threshold detector. (24), its output coupled to a signal input (28) of the shift register (27), at least one output of which is coupled to the other of the outputs (14) of the analysis block (11). 3. Connection according to claim 2, characterized in that an inverter is connected between the output of the at least one threshold detector (24) and / or the output of the at least one shift register (27) and the output (14) of the analysis block (11). 4. A circuit as claimed in any one of claims 1 to 3, characterized in that a first of the control inputs (35) of the elimination signal source (34) is connected to the code input (16) of the evaluation member (15), the output of which is connected to the elimination an output (18) of the evaluation member (15), wherein at least one other of the control inputs (35) of the source (34) of the elimination signal source is coupled to its output by a conditional member (30), each of which at least two inputs is connected to one conditional inputs (17) of the evaluation member (15). '5. The circuit according to claim 4, characterized in that the output of at least one of the condition members (30) is connected to a modification output (19) of the evaluation member (15). 6. The circuit according to claim 4, wherein at least one of the condition members comprises a condition threshold detector, the output of which is coupled to the output of the condition member, and to which the branching resistor network output is connected. formed by interconnected second terminals of resistors (32), which are a resistor network and whose first terminals are connected to one of the inputs of the conditional member (30). 7. The circuit according to claim 6, wherein a logic sum gate (31) is connected to the first terminal of at least one of the detectors (32) and connected to one of the conditional inputs by each of its at least two inputs. (30). 8. The circuit according to claim 4, wherein at least one of the condition members (30) is a logic product circuit. Connection according to one of Claims 4 to 8, characterized in that a sampling input (36) of the source of elimination signals (34) is connected to the output of the accumulation member (7). 2 sheets of drawings