JPH04107030A - Transmission signal error detector - Google Patents

Abstract

PURPOSE:To check error with one bit as the unit by digitizing an inputted transmission signal by a comparator group to apply this signal to a sequence means and outputting the transmission signal from the sequence means in the case of the signal from each comparator within an allowable range for the transmission signal but outputting an error signal from the sequence means in the case of the signal from each comparator beyond this range. CONSTITUTION:A transmission signal error detector is presented which discriminates whether the transmission signal is good or not with each bit as the unit and performs error check and filter action to output transmission data. This detector consists of a group 1 of plural comparators which take a signal Vi to be transmitted as the input and compare the level of this signal with signals of prescribed levels and a sequence means 2 which receives the signal from each comparator of the comparator group 1 and discriminates whether the signal from each comparator has an allowable level and its level continues for an allowable time or not. When it is within the allowable range, this means outputs the transmission data signal; but otherwise, the means 2 outputs the error signal.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a transmission signal error detection device used in a data communication system. The present invention relates to a transmission signal error detection device that detects a transmission error, outputs an error, and outputs a signal to enable accurate signal transmission.

<Prior Art> Generally, in data communication, it is required that data be transmitted accurately without transmission errors.

The cause of transmission errors is external noise.

Examples include transmission distortion caused by reflection, frequency characteristics of the transmission path, and the like. To reduce this transmission error, there are methods such as inserting a filter, differential receiver, and insulation to reduce external noise, and methods to reduce reflections such as selecting a termination resistor with an optimal value. Regarding the frequency characteristics of the transmission line, methods such as using cables as thick as possible are taken.

However, transmission distortion is unavoidable in long-distance, high-speed transmission.

For this reason, parity bits have been conventionally added to transmission data in order to improve the reliability of the transmission data.

<Problems to be Solved by the Invention> According to such conventional devices, since there is no means to directly know on a bit-by-bit basis code reading errors caused by transmission distortion, it is difficult to maintain even higher reliability. There was a problem.

The present invention has been made in view of the above points, and an object of the present invention is to provide a transmission signal error detection device that determines the pass/fail of a transmission signal bit by bit, performs error checking and filtering, and outputs transmission data. shall be.

Means for Solving the Problems> FIG. 1 is a block diagram showing the basic configuration of the present invention.

In the figure, 1 is a plurality of comparator groups that manually input the signal Vi to be transmitted and compares the level of this signal with a signal of a predetermined level; 2 is a group of comparators that receives signals from each of these comparator groups 1; A sequence means that determines whether the signal is at an acceptable level and continues for an acceptable period of time, outputs transmission data (signal) if it is within the acceptable range, and outputs transmission data (signal) if it is not acceptable. Outputs an error signal.

Function> The comparator group digitizes the input transmission signal and applies it to the sequence means.

The sequence means outputs a transmission signal if the signal to be transmitted is within a permissible range with respect to the signal from each comparator, and outputs an error signal when the signal is outside the permissible range.

<Example> Embodiments of the present invention will be described in detail below with reference to the drawings.

FIG. 2 is a block diagram showing an embodiment of the present invention. In the figure, the comparator group 1 includes four comparators 11 to 14, in which a transmission signal Vi is applied to one input terminal, and signals VLo, VTL, and VTL of different levels are applied to the other input terminal. VTH, VHi
is applied.

FIG. 3 is a diagram showing an example of a transmission signal. If the signal level changes in the positive/negative direction with a duty ratio of 50% within the time width representing 1 bit, the code is "0".If the signal level does not change within the time width representing 1 bit, the code is "1". It is designed to represent

FIG. 4 shows comparison voltage signals VLo, VT set to each comparator 11 to 14 for such a transmission signal Vi.
The magnitude of L, VTH, VHi and the sign r of the transmission signal Vi
It is a figure showing the case of OJ.

The voltage levels VLo and VTL are the lower limit value V of the transmission signal ■i
With respect to iL, the relationship is VLo<V i L<VTL, and the voltage levels VTH and VHi are in the relationship VTH<V i H<V with respect to the upper limit ViH of the transmission signal Vi.
The relationship is Hi.

By selecting the magnitude of the comparison voltage set in each of the comparators 11 to 14 in this manner, a window for determining whether the code "0" of the transmission signal Vi is acceptable can be set.

In other words, such a window is set at the same time as the rising edge of the transmission signal Vi appears, and if the transmission signal Vi passes through this window, it is passed, and the signal is output as is, and if the signal passes through the shaded area, then It is considered an error.

FIG. 5 is a diagram showing various distortion states of the transmission signal V1 with respect to a set window. In case (a), the transmission signal V1 passes through the set window, so it is passed, and in case (b), it passes through the shaded area, so it is judged as an error. .

In addition, there is no rising edge of the transmission signal Vi (symbol "
1), the signal is output as is.

FIG. 6 is a state transition diagram of the sequence means 2 for inputting the signals from each of the comparators 11 to 14 and determining whether the transmission signal is acceptable or not as described above. The sequence means 5 is composed of a digital circuit including a timer, and receives four signals Lo and TL from each of the comparators 11 to 14.
, TH, Hi (Hi, Lo are the maximum and minimum values of positive and negative potentials allowed for the transmission signal) are input.

P, C, and N shown here are in the following states, respectively.

P;Hi-1 C, TH-0 and TL-O N;Lo-1 The following items are checked here.

(a) A state change to CP is determined to be a rising edge.

(b) The state change to NP is determined to be a rising edge.

(c) P continues for more than 10 sample times.

(d) P is less than or equal to 20 sample times ((e)
, (f) is the end of P).

(e) The state change to PN is determined to be a falling edge.

(f) The state change to P-C is determined to be a stand-down edge.

(g) In the case of a stand-down edge, N must be detected within 6 sampling times.

(h) N continues for more than 10 sample times.

(i) N is less than or equal to 20 sample times.

(j) Determine the state change to N-''P as a rising edge (same as (b)).

The state change to (k,)NC is determined to be a desk start edge.

When checking each of these items, if there is an error, an error flag is set and the next signal is determined. By performing these checks, it is possible to sequentially determine whether the code "0" of the transmission signal is within the specified window, and if there is no error, the transmission signal is output as is, and if an error is detected, it is output. An error signal is output.

In this example, one sampling time is one bit length of the transmission signal divided into 32.

<Effects of the Invention> As described in detail above, according to the present invention, errors can be checked in units of 1 bit, thereby improving the reliability of data.

Furthermore, since the window can be set arbitrarily, the noise margin to be sealed in the transmission signal can be freely determined. In particular, the settings can be made on the time axis.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing the basic configuration of the present invention, Fig. 2 is a block diagram showing an embodiment of the invention, Fig. 3 is a diagram showing an example of a transmission signal, and Fig. 4 is a transmission signal. Figure 5 shows the magnitude of the comparison voltage signal set to each comparator and the waveform when the code of the transmission signal is "0". Figure 5 shows various distortion states of the transmission signal for the set window. FIG. 6 is a state transition diagram of a sequence means for inputting signals from each comparator and determining pass/fail of a transmitted signal. 1... Comparator group 2... Sequence means 1
1 to 14... Converter (b) Vi

Claims (1)

[Claims] A plurality of comparator groups inputting a signal to be transmitted and comparing the level of the signal with a signal of a predetermined level, and receiving signals from each of these comparator groups, and a sequence means for determining whether the transmitted signal is at an acceptable level and continues for an acceptable period of time, and outputs a signal if the transmitted signal is within an acceptable range. A transmission signal error detection device that outputs an error signal if the signal is out of the specified range.