JP2001053656A - Data transmission device and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce unnecessary noise by setting an output amplitude corresponding to the attenuation quantity or cable length of a transmission line. SOLUTION: This device comprises a transmitting circuit 11 which outputs a transmit signal, a variable attenuating circuit 12 which attenuates the amplitude of the signal outputted from the transmitting circuit, a receiving circuit 13 which receives the transmit signal, and an attenuation quantity measuring circuit 14. Transmit signals are sent and received between data transmission devices and the attenuation quantity measuring circuit measures the attenuation quantity of the receive signal to adjust the attenuation of the transmit signal by the variable attenuating circuit 12.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to reduction of electromagnetic noise in data transmission.

[0002]

2. Description of the Related Art Conventionally, when an electric cable is used to connect devices, electromagnetic waves (hereinafter referred to as radiation noise) are used.
The problem of MI (Electro Magnetic Interference) existed. In recent years, with the increase in transmission speed and the number of cables, the influence of radiation noise radiated from cables has increased, and there is concern not only about malfunctions of electronic devices but also about human bodies. Therefore,
Each country has a standard value for these radiated noises. For example, in Japan, VCCI (Voluntary Control Council for Int.
erference by Data Processing Equipment and Electro
nic Office Machines). However, at present, the transmission speed is increasing and the number of cables is increasing, and it is becoming very difficult to configure a transmission device satisfying these standard values. In addition, some electronic devices and the like may cause their own devices to malfunction due to radiation noise generated by themselves, which is also a recent problem.

In view of such a problem, for example, Japanese Patent Application Laid-Open
JP-A-84124 discloses a method of reducing noise radiated from a cable by inserting a noise reduction circuit between a female connector and a male connector of a high-speed bus.

[0004]

However, in the above-mentioned prior art, since the noise reduction circuit attenuates even the necessary signal components, the noise reduction circuit attenuates the signal having a high transmission speed or the signal requiring long-distance transmission. There was a problem that it could not cope.

An object of the present invention is to reduce unnecessary radiation noise by setting an output amplitude according to a transmission path attenuation or a cable length. Specifically, the attenuation of the transmission line is measured by an attenuation measuring circuit, and the output amplitude is attenuated by a variable attenuation circuit in accordance with the amount of attenuation, so that transmission is performed with a minimum amplitude necessary for each transmission line. To output a signal.

[0006]

According to the present invention, there is provided a data transmission apparatus for inputting / outputting a transmission signal via a transmission line, comprising: a transmission circuit for outputting a transmission signal; An attenuation measurement circuit that receives a transmission signal from another data transmission device and measures the amplitude thereof, and applies a predetermined change to the transmission signal output from the transmission circuit according to the measurement result of the attenuation measurement circuit. And an adjusting circuit for sending the data to the other data transmission device.

Another data transmission apparatus according to the present invention is a data transmission apparatus for inputting and outputting a transmission signal via a transmission path, wherein the transmission circuit outputs a transmission signal, and the transmission signal output from the transmission circuit is provided. A variable attenuating circuit for attenuating the amplitude of the signal and sending it to another data transmission device, and a transmission signal from another data transmission device, including an attenuation measuring circuit for measuring the amplitude, wherein the attenuation measuring circuit is The attenuation of the transmission signal in the variable attenuation circuit is set according to the magnitude of the amplitude of the transmission signal from the other data transmission device.

The variable attenuation circuit has a fixed resistance or a variable resistance having a plurality of different resistance values, and attenuates the transmission signal by switching the resistance value according to the setting of the attenuation amount measurement circuit.

Further, the attenuation measuring circuit has at least one comparator for comparing an amplitude of a transmission signal from the another data transmission device with a reference voltage, and the variable amount is determined based on a comparison result of the comparator. Set the resistance value of the attenuation circuit.

Further, the data transmission device includes a tr / tf adjusting circuit for adjusting a rise time and a fall time of a transmission signal, instead of the variable attenuating circuit, and the attenuation measuring circuit includes The setting of the rise time and the fall time in the tr / tf adjustment circuit is switched according to the magnitude of the signal amplitude.

Further, a data transmission method according to the present invention is a data transmission method for a data transmission apparatus which is connected to each other via a transmission path and transmits / receives a transmission signal via the transmission path. It transmits and receives to and from another data transmission device via a transmission path, measures the amplitude of a transmission signal received from the other data transmission device, and transmits the signal to the other data transmission device according to the measured amplitude. Attenuate the signal.

Further, another data transmission method according to the present invention includes:
A data transmission method for a data transmission device which is mutually connected via a transmission path and transmits / receives a transmission signal via the transmission path, wherein the transmission signal is transmitted to / from another data transmission apparatus via the transmission path. The amplitude of a transmission signal transmitted / received and received from another data transmission device is measured, and the rise time and the fall time of the transmission signal with respect to the other data transmission device are changed according to the measured amplitude.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, a first embodiment of the present invention will be described in detail with reference to the drawings.

Referring to FIG. 1, a data transmission apparatus 10 of the present invention includes a transmission circuit 11 for outputting a transmission signal, and a variable attenuation circuit for attenuating the amplitude of the signal as an adjustment circuit for the signal output from the transmission circuit 11. 12, a receiving circuit 13 for receiving a transmission signal from another data transmission device 20, and an attenuation measuring circuit 14. Other data transmission devices 20 include transmission lines 110 and 1 for transmitting transmission signals.
The data transmission device 10 is connected to the data transmission device 10 via the data transmission device 20. Similarly to the data transmission device 10, the data transmission device 20 includes a transmission circuit 22, a variable attenuation circuit 22, a reception circuit 23, and an attenuation measurement circuit 24, respectively.

The transmission signal output from the transmission circuit 11 of the data transmission device 10 passes through the variable attenuation circuit 12 and is received by the reception circuit 23 of another data transmission device 20 connected via the transmission line 110. This transmission signal is also branched and input to the attenuation measuring circuit 24 at the same time. Similarly, a transmission signal output from the transmission circuit 22 of the data transmission device 20 is input to the reception circuit 13 and the attenuation measurement circuit 14 of the data transmission device 10 via the transmission path 120. here,
It is assumed that the transmission lines 110 and 120 have the same cable length, and that the variable attenuation circuits 12 and 22 are set to a state of no attenuation as an initial value. The attenuation measuring circuits 14 and 24 measure the amplitudes of the received transmission signals, respectively, and according to the amplitudes, the variable attenuation circuits 12 and 2
The instruction of the amount of attenuation in 2 is performed.

Next, the operation of the first embodiment of the present invention will be described with reference to the drawings.

Referring to FIG. 2, first, transmission circuits 11 and 21 output transmission signals having the same amplitude (step S1 in FIG. 2). In the initial setting, the variable attenuating circuits 12 and 22 have no attenuation, and the transmission signal is transmitted to the transmission lines 110 and 120 without attenuation, respectively. The attenuation measuring circuit 14 transmits the transmission signal output from the transmission circuit 21 in the data transmission device 20 to the transmission line 1.
20 (step S2). Next, the attenuation measuring circuit 14 measures the amplitude of the received transmission signal and determines whether or not the amplitude is larger than the minimum amplitude that can be received by the data transmission apparatus 10 of its own, that is, the amplitude that can be received. It is determined whether or not there is room (step S3). If there is a margin, the attenuation measurement circuit 14 instructs the attenuation setting in the variable attenuation circuit 12 in accordance with the magnitude of the received transmission signal with respect to the minimum receivable amplitude (step S).
4). On the other hand, if there is no margin in the amplitude of the received transmission signal, the state of the variable attenuation circuit 12 is maintained (Step S).
5). The data transmission device 20 operates in the same manner as the data transmission device 10 after step S2. By such an operation, the transmission signals output from the data transmission devices 10 and 20 are optimally adjusted, useless output is suppressed, and radiation noise can be minimized.

Next, an embodiment of the present invention will be described with reference to FIGS. FIG. 3 shows output waveforms and received waveforms in the data transmission devices 10 and 20. First, the output amplitude Vo from each of the transmission circuits 11 and 21 is output.
(FIG. 3A), the variable attenuation circuits 12 and 22 are initially set to have no attenuation, so that the transmission signal is output to the transmission lines 110 and 120 while maintaining the output amplitude Vo. Sent out. The output transmission signal is attenuated according to the cable lengths of the transmission lines 110 and 120, respectively. Hereinafter, the data transmission device 1
Although the operation at 0 will be described, the data transmission device 20 operates similarly. The transmission signal is 0.
Assuming that attenuation of 2 Vo has occurred, as a result, the receiving circuit 1
3 and the attenuation measuring circuit 14 obtain a reception amplitude of 0.8 Vo (FIG. 3B). Data transmission device 1
The minimum receivable amplitude at 0 is 0.4 Vo (see FIG. 3).
In the case of (c)), the attenuation measuring circuit 14 detects that there is a margin in the amplitude of the transmission signal with respect to the minimum receivable amplitude. That is, this means that radiation noise is generated due to the extra high output. Therefore, the attenuation measuring circuit 14 instructs the variable attenuation circuit 12 to attenuate the output amplitude.

Referring to FIG. 4, the attenuation measuring circuit 14
Is composed of a comparator 31 and a decoder 32 for comparing a reference voltage with a reception amplitude. Further, the received amplitude may be converted to a digital value using an analog-to-digital converter. The variable attenuating circuit 12 includes the attenuation measuring circuit 1
4, the amount of attenuation is changed. here,
The configuration is such that the two reference values of 0.8 Vo and 0.6 Vo are compared with the reception amplitude. This is because the amount of attenuation is changed stepwise according to the magnitude of the reception amplitude. A configuration in which the received amplitude is compared with only one reference voltage may be used as long as the amount of attenuation is constant. The number of reference voltages to be compared and the reference voltage value need not be limited to the present embodiment, and may be set as appropriate.

Referring to FIG. 5, the variable attenuation circuit 12 includes:
A fixed resistor 41 or a MOS FET having a different resistance value is inserted in series with the output, and these are switched by a switch 42 (MOS FET, relay, etc.) in accordance with the output of the attenuation measuring circuit 14. Here, the variable attenuating circuit 12 is configured to perform stepwise switching using fixed resistors 41 having different resistance values. However, the variable attenuating circuit 12 uses a variable resistor instead of the fixed resistor 41 to change the resistance according to each reception amplitude of the transmission signal. Of course, a configuration for switching the value may be used.

The attenuation set in accordance with the output of the attenuation measuring circuit 14 is set in advance according to the amplitude that the receiving circuit 13 can receive. For example, when the minimum receivable amplitude is 0.4 Vo (FIG. 3C),
When the reception amplitude is less than 60% (0.6 Vo) with respect to the output amplitude Vo in the attenuation amount measuring circuit 14, "0" is selected to not attenuate the output amplitude, and the reception amplitude is 60 to 80%.
In the case of (0.5 to 0.8 Vo), "1" is selected to attenuate the output amplitude by 0.2 Vo, and the reception amplitude is 80% (0.
8V), the variable attenuation circuit 1 selects “2” to attenuate the output amplitude by 0.4 Vo and outputs the result.
Switch between 2 and 22.

When a variable resistor is used, the amount of attenuation of the output amplitude may be adjusted according to each reception amplitude, and the resistance value may be appropriately selected so that the reception amplitude becomes a predetermined receivable amplitude.

With the above configuration, the transmission signals output from the transmission circuits 11 and 21 with the amplitude Vo are output from the variable attenuation circuit 12 and
Since the signal is appropriately attenuated at 22 and transmitted to the transmission lines 110 and 120, radiation noise radiated from the transmission lines 110 and 120 is reduced.

In this embodiment, the transmission path of the data transmission device is 1
Although the case of pairs (two) has been described, the same applies when the data transmission apparatus has n pairs (n × 2) of transmission paths. Also, the number of stages of attenuation need not be two, but may be set appropriately.

Next, a second embodiment of the present invention will be described with reference to the drawings. Referring to FIG. 6, a second embodiment of the present invention is shown.
In the embodiment, the variable attenuation circuit 1 of the first embodiment is used.
Tr / tf adjustment circuit 1 for changing the rise time (tr) and fall time (tf) of the transmission signal instead of 2, 22
5, 25 are provided.

Referring to FIG. 7, the tr / tf adjustment circuit 15,
25 adds capacitors 51 to 53 (capacitor capacitance: capacitor 51 <capacitor 52 <capacitor 53) having different capacities to the output, and switches them by a switch 54 (MOS FE).
T, relay, etc.) to smooth the waveform.

As in the first embodiment, the amount of attenuation of the received signal is measured, and the rise time and fall time are adjusted by the tr / tf adjustment circuit according to the result. Referring to FIG. 8, in a transmission line having a short cable length and a small attenuation, tr
By reducing / tf to suppress high-frequency components, radiation noise is reduced (Fig. 8 (a)), and conversely, by increasing tr / tf as the transmission path becomes longer and the transmission path becomes larger and more attenuated. The minimum receivable amplitude may be secured (see FIG. 8).
(B), (c)).

The tr / tf set according to the output of the attenuation measuring circuit 14 is set in advance in accordance with the receivable amplitude of the receiving circuit 13 as in the case where the variable attenuation circuit 12 is used. For example, if the minimum receivable amplitude is 0.4 Vo (FIG. 3 (c)), the reception amplitude in the attenuation measuring circuit 14 is 60% of the output amplitude Vo.
If it is less than (0.6 Vo), “0” is selected and FIG.
As shown in (a), the capacitor 51 with the minimum tr / tf is selected, and the reception amplitude is 60 to 80% (0.5 to 0.8 Vo).
In the case of, "1" is selected and 2tr / t is selected as shown in FIG.
Select the capacitor 52 that becomes f, and make the reception amplitude 80%
If it is larger than (0.8 Vo), "2" is selected, and the tr / tf adjusting circuits 15 and 25 are switched so as to select the capacitor 53 having 3 tr / tf as shown in FIG. 8C.

As described above, according to the embodiment of the present invention, the attenuation measuring circuits 14 and 24 are provided in each data transmission device, and the attenuation of the output amplitude or tr / tf is changed according to the reception amplitude of the transmission signal. By doing so, it is possible to suppress the generation of unnecessary transmission signals, and to reduce radiation noise generated by unnecessary high output.

[0030]

As is apparent from the above description, according to the present invention, unnecessary radiation noise can be reduced by attenuating the transmission signal to the minimum output amplitude necessary for each transmission path and transmitting the signal. It becomes possible. Alternatively, unnecessary radiation noise can be reduced by adjusting and changing tr / tf according to the amount of attenuation of the received signal due to the transmission path.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a flowchart illustrating an operation of the exemplary embodiment of the present invention.

FIG. 3 is a diagram illustrating a transmission signal according to the first embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of an attenuation measuring circuit according to the present invention.

FIG. 5 is a block diagram illustrating a configuration of a variable attenuation circuit according to the present invention.

FIG. 6 is a block diagram showing a configuration of a second exemplary embodiment of the present invention.

FIG. 7 is a block diagram illustrating a configuration of a tf / tr adjustment circuit according to the present invention.

FIG. 8 is a diagram illustrating a transmission signal according to the second embodiment of the present invention.

[Explanation of symbols]

 10, 20 Data transmission device 11, 21 Transmission circuit 12, 22 Variable attenuation circuit 13, 23 Attenuation measurement circuit 14, 24 Receiving circuit 15, 25 tf · tr adjustment circuit 31 Comparator 32 Decoder 41 Fixed resistor 42, 54 Switch 51 , 52, 53 Condenser 110, 120 Transmission line

Claims (11)

[Claims] 1. A data transmission device for inputting and outputting a transmission signal via a transmission line, comprising: a transmission circuit for outputting a transmission signal; and an attenuation device for receiving a transmission signal from another data transmission device and measuring its amplitude. An amount measuring circuit, and an adjusting circuit for applying a predetermined change to the transmission signal output from the transmission circuit according to the measurement result of the attenuation amount measuring circuit and transmitting the signal to the other data transmission device. Data transmission device. 2. The data transmission device according to claim 1, wherein the adjustment circuit is a variable attenuation circuit that attenuates the amplitude of the transmission signal by a predetermined value. 3. The data transmission device according to claim 1, wherein the adjustment circuit is a tr / tf adjustment circuit that adjusts rise and fall times of the amplitude of the transmission signal. 4. A data transmission device for inputting and outputting a transmission signal via a transmission line, comprising: a transmission circuit for outputting a transmission signal; and a data transmission device for attenuating the amplitude of the transmission signal output from the transmission circuit to perform another data transmission. A variable attenuating circuit for sending to the device, and an attenuation measuring circuit for receiving a transmission signal from another data transmission device and measuring the amplitude thereof, wherein the attenuation measuring circuit transmits the signal from the other data transmission device. A data transmission device, wherein an attenuation of a transmission signal in the variable attenuation circuit is set according to a magnitude of a signal amplitude. 5. The variable attenuation circuit has a plurality of fixed resistances or variable resistances having different resistance values, and attenuates a transmission signal by switching resistance values according to the setting of the attenuation amount measurement circuit. The data transmission device according to claim 2 or 4, wherein 6. The attenuation measuring circuit has at least one comparator for comparing an amplitude of a transmission signal from the another data transmission device with a reference voltage, and the variable amount is determined based on a comparison result of the comparator. The data transmission device according to claim 5, wherein a resistance value of the attenuation circuit is set. 7. The data according to claim 6, wherein the attenuation measuring circuit sets the resistance value of the variable attenuation circuit to be larger as the amplitude of the transmission signal from the other data transmission device is larger. Transmission equipment. 8. The data transmission device includes a tr / tf adjustment circuit that adjusts a rise time and a fall time of a transmission signal, instead of the variable attenuation circuit, 5. The data transmission apparatus according to claim 4, wherein the setting of the rise time and the fall time in the tr / tf adjustment circuit is switched according to the magnitude of the signal amplitude. 9. The attenuation measuring circuit according to claim 1, wherein the larger the amplitude of the transmission signal from the other data transmission device, the larger the tr / tf
9. The data transmission device according to claim 8, wherein a rise time and a fall time of the adjustment circuit are set long. 10. A data transmission method for a data transmission device which is connected to each other via a transmission path and transmits / receives a transmission signal via the transmission path, wherein the transmission signal is transmitted to another data via the transmission path. Transmitting and receiving to and from a transmission device, measuring the amplitude of a transmission signal received from another data transmission device, and attenuating the transmission signal to the other data transmission device according to the magnitude of the measured amplitude. Data transmission method. 11. A data transmission method for a data transmission device connected to each other via a transmission path and transmitting / receiving a transmission signal via the transmission path, wherein the transmission signal is transmitted to another data via the transmission path. The amplitude of a transmission signal transmitted / received to / from a transmission device and received from another data transmission device is measured, and the rise time and the fall time of the transmission signal to the other data transmission device according to the measured amplitude are measured. A data transmission method characterized by changing the data transmission.