JPH06177798A - Transmitter - Google Patents

Abstract

PURPOSE:To send a signal with the optimized noise level at all times under dissimilar conditions by reproducing an output signal by sending a signal pre- emphasized at the side of transmission and de-emphasizing a signal received at the side of reception. CONSTITUTION:A soundless signal transmission circuit 22 sends a soundless signal for constant time intervals. A variable pre-emphasis circuit 21 of a communication equipment 20 at the side of transmission outputs signals by pre- emphasizing the soundless signal by the pre-emphasis characteristic. The pre- emphasized signal is sent to a communication equipment 30 at the side of reception. In the equipment 30, a variable de-emphasis circuit 31 outputs signals by de-emphasizing the pre-emphasized signal by the de-emphasis characteristic. A BPF 32 detects the noise level of the signal and outputs a detection noise level signal. A control circuit 33 differentiates the level signal by time and outputs a control signal. The control signal is sent to the communication equipment 20 where the circuit 21 changes the pre-emphasis characteristic to minimize noises.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a low noise transmission device for transmitting a signal such as an audio signal or an image signal from a transmitting side to a receiving side via a transmission line.

[0002]

As is well known, when a signal such as an audio signal or an image signal is transmitted from a transmitting side to a receiving side through a transmission line by frequency modulation type communication, the SN ratio is high at a high frequency of the modulated signal. Becomes worse. In order to improve this, it has been performed in advance that the transmitting side strongly applies modulation to high frequencies. Such an operation performed on the transmitting side is called pre-emphasis, and a circuit that performs pre-emphasis is called a pre-emphasis circuit. Generally, such a pre-emphasis circuit is composed of a differentiating circuit. On the other hand, on the receiving side, in order to reproduce faithfully, it is necessary to restore the pre-emphasized signal. This kind of operation is called de-emphasis,
A circuit that performs de-emphasis is called a de-emphasis circuit. Usually, this de-emphasis circuit is composed of an integrating circuit consisting of a capacitor and a resistor.

In a conventional transmission device, a signal is transmitted from a transmission side to a reception side by a fixed emphasis characteristic. In other words, the transmitting side is provided with a fixed pre-emphasis circuit having a preset pre-emphasis characteristic, and the receiving side is also provided with a fixed de-emphasis circuit having a preset de-emphasis characteristic.

[0004]

[Problems to be Solved by the Invention] When transmitting a signal,
The noise level fluctuates due to environmental conditions such as temperature changes or loss in the transmission path. Therefore, there is a problem in that it is difficult to say that a signal having a noise level that is always optimized is transmitted when a signal is transmitted with a fixed emphasis characteristic as in the conventional transmission device.

Therefore, an object of the present invention is to provide a transmission device capable of transmitting a signal whose noise level is always optimized under different conditions.

[0006]

A transmission apparatus according to the present invention pre-emphasiss an input signal to be sent to a reception side on a transmission side, sends out the pre-emphasized signal to a transmission line, and the reception side transmits the signal from the transmission line. The received pre-emphasized signal is de-emphasized to reproduce the output signal corresponding to the input signal.

The transmission apparatus according to the present invention comprises a variable pre-emphasis circuit for pre-emphasizing an input signal with a variable pre-emphasis characteristic and outputting a pre-emphasized signal to the transmitting side, and a silent signal as a variable pre-emphasis circuit. And a silent signal sending circuit to supply to
A variable de-emphasis circuit that de-emphasizes the pre-emphasized signal with a variable de-emphasis characteristic and outputs the output signal to the receiving side, and the noise of the output signal when the silence signal is sent as the input signal by the silence signal sending circuit. A noise level detecting means that detects a level and outputs a detected noise level signal that represents the detected noise level, and pre-emphasis characteristics and de-emphasis characteristics that minimize the noise level based on the detected noise level signal are specified. A control circuit for determining a control signal to be supplied to the variable de-emphasis circuit, and a feedback transmission line for transmitting the control signal from the receiving side to the transmitting side to provide the control signal to the variable pre-emphasis circuit. To do.

[0008]

Embodiments of the present invention will now be described in detail with reference to the drawings.

Referring to FIG. 1, a transmission apparatus according to an embodiment of the present invention pre-emphasiss an input signal to be transmitted to a reception side at a transmission side, transmits the pre-emphasized signal to a transmission line 10, and then a reception side. In this case, the pre-emphasized signal received from the transmission line 10 is de-emphasized to reproduce the output signal corresponding to the input signal.

The transmission apparatus of this embodiment has a transmission side communication equipment 20 and a reception side communication equipment 30 connected to each other via a transmission line 10.

The transmission side communication equipment 20 is provided with a variable pre-emphasis circuit 21 for pre-emphasizing an input signal with a variable pre-emphasis characteristic and outputting a pre-emphasized signal. This variable pre-emphasis circuit 21
A silence signal sending circuit 22 is provided on the input side of. The silence signal sending circuit 22 uses a silence signal as an input signal at a variable pre-emphasis circuit 21 at predetermined time intervals.
Is supplied to.

The receiving side communication equipment 30 is provided with a variable de-emphasis circuit 31 which de-emphasizes the pre-emphasized signal with a variable de-emphasis characteristic and outputs an output signal. This variable de-emphasis circuit 31
A bandpass filter 32 is provided on the output side of. The bandpass filter 32 is used for the silent signal transmission circuit 22.
Serves as a noise level detecting means for detecting the noise level of the output signal when a silent signal is transmitted as the input signal. The bandpass filter 32 outputs a detected noise level signal representing the detected noise level. This detected noise level signal is supplied to the control circuit 33. Control circuit 33
Calculates a control signal that defines the pre-emphasis characteristic and the de-emphasis characteristic such that the noise level is minimized based on the detected noise level signal. Control circuit 33
Is the variable de-emphasis circuit 3
Give to one. In response to this control signal, the variable de-emphasis circuit 31 changes its de-emphasis characteristic.

A feedback transmission line 11 is provided between the receiving side and the transmitting side. This feedback transmission line 11 connects between the control circuit 33 on the receiving side and the transmitting side communication equipment 20 on the transmitting side. The feedback transmission line 11 is for giving the control signal obtained by the control circuit 33 to the variable pre-emphasis circuit 31.

The transmission side communication facility 20 includes a memory circuit 23 connected to the feedback transmission line 11. The memory circuit 23 holds the control signal sent from the feedback transmission line 11, and supplies the held control signal to the variable pre-emphasis circuit 31. The memory circuit 23 holds the previous control signal until the next control signal is sent. In response to the control signal held in the memory circuit 23, the variable pre-emphasis circuit 31 changes its pre-emphasis characteristic.

Referring to FIG. 2, control circuit 33 shown in FIG.
Is an amplifier 331, a rectifier circuit 332, and a differential amplifier 3
33, a differentiating circuit 334, an adding circuit 335, a DC amplifier 336, and a memory circuit 337. The detection noise level signal that has passed through the bandpass filter 32 (FIG. 1) is amplified by the amplifier 331 and then rectified by the rectifier circuit 332. The rectified signal V output from the rectifier circuit 332 is supplied to the non-inverting input terminal of the differential amplifier 333.
The rectified signal V is supplied to the differentiating circuit 334, which differentiates the rectified signal V with respect to time,
The differentiated signal dV / dt is output. The differentiated signal dV / dt is supplied to one input terminal of the adder circuit 335. The rectified signal V is supplied to the other input terminal of the adder circuit 335. The adder circuit 335 adds the rectified signal V and the differentiated signal dV / dt, and outputs the added signal (V + dV / dt). This added signal (V
+ DV / dt) is supplied to the inverting input terminal (reference terminal) of the differential amplifier 333. The differential amplifier 333 is
The difference between the rectified signal V and the added signal (V + dV / dt) is obtained, and the difference signal v representing this difference is output. This difference signal v is supplied to the DC amplifier 336. DC amplifier 3
36, the difference signal v is DC-amplified and DC-amplified and output. The DC-amplified signal is held in the memory circuit 337. The memory circuit 337 outputs the held signal as a control signal.

By this control signal, the pre-emphasis characteristic of the variable pre-emphasis circuit 21 and the de-emphasis characteristic of the variable de-emphasis circuit 31 are controlled so that the noise level becomes minimum. Here, the difference signal v output from the differential amplifier 333 is the rectifier circuit 332.
The noise level approaches the minimum value as it approaches the rectified signal V output from.

Next, the operation of the transmission apparatus of this embodiment will be described.

The silent signal sending circuit 22 sends a silent signal at certain intervals. The variable pre-emphasis circuit 21 of the transmission-side communication equipment 20 outputs a pre-emphasized signal by pre-emphasising a silent signal with a certain pre-emphasis characteristic. The pre-emphasized signal is transmitted to the receiving side communication facility 30 via the transmission line 10. In the receiving side communication equipment 30, the variable de-emphasis circuit 3
Reference numeral 1 de-emphasizes a pre-emphasized signal with a certain de-emphasis characteristic and outputs an output signal. The band pass filter 32 detects the noise level of this output signal and outputs a detected noise level signal representing the detected noise level. The control circuit 33 time-differentiates the detected noise level signal and outputs a control signal. This control signal is transmitted to the transmitting-side communication facility 20 via the feedback transmission line 11. In the transmission-side communication facility 20, the memory circuit 23 holds the control signal and gives the held control signal to the variable pre-emphasis circuit 21. In response to the control signal, the variable pre-emphasis circuit 21 changes the pre-emphasis characteristic so that the noise level is minimized.

At this time, the level difference between the signal on the transmitting side before pre-emphasis (input signal) and the signal on the receiving side after de-emphasis (output signal) must always be constant. Therefore, it is necessary to change the de-emphasis characteristic of the variable de-emphasis circuit 31 by the amount of the change of the pre-emphasis characteristic of the variable pre-emphasis circuit 21. Therefore, in the present embodiment, the control circuit 33 also supplies a control signal to the variable de-emphasis circuit 31 so that the de-emphasis characteristic of the variable de-emphasis circuit 31 is always set to the pre-emphasis characteristic and the inverse characteristic of the variable pre-emphasis circuit 21. Has been changed to

The control signal sent from the control circuit 33 via the feedback transmission line 11 is held by the memory circuit 23 of the transmission side communication equipment 20 until the next control signal is sent. Here, when the feedback transmission path 11 is disconnected, the variable pre-emphasis circuit 2
1 fixes its pre-emphasis characteristic to a predetermined one. Then, the variable pre-emphasis circuit 21 sends an alarm signal to the receiving side communication facility 30 via the transmission line 10. In the receiving side communication facility 30, the variable de-emphasis circuit 31 fixes the de-emphasis characteristic to a predetermined one in response to the alarm signal.

In this example, when the feedback transmission line is disconnected, the variable pre-emphasis circuit 21 and the variable de-emphasis circuit 31 fix the pre-emphasis characteristic and the de-emphasis characteristic which are predetermined, respectively. Feedback transmission line 1
You may make it fix to the state before 1 was disconnected.

FIG. 3 shows the emphasis level-noise characteristics. Noise has a local minimum at a fixed emphasis level under certain conditions. However, under different environmental conditions, the minimum emphasis level also fluctuates. Therefore, in the present invention, the control circuit 33 automatically sets the emphasis level (pre-emphasis characteristic and de-emphasis characteristic) that always minimizes noise.

FIG. 4 shows a time-output signal characteristic in the output signal detected under the condition shown in FIG. It can be seen from the characteristic curve shown by the solid line in FIG. 3 that the output signal converges as the emphasis level approaches the minimum value as time passes from t ₁ to t ₆ .

As the bandpass filter 32, C
CIR (International Committee on Radio Communications) Recommendation (468-4)
It is preferable to use a filter having an evaluation characteristic according to
By using this filter, the SN ratio can be optimized so as to reduce the noise that the human ear feels, rather than improving the physical SN ratio.

[0025]

As described above, according to the transmission apparatus of the present invention, the pre-emphasis characteristic of the variable pre-emphasis circuit on the transmitting side and the de-emphasis characteristic of the variable de-emphasis circuit on the receiving side are always minimized. Since it is controlled so that the noise is always kept to a minimum even under different conditions, a good output signal can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a transmission device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a detailed configuration of a control circuit in FIG.

FIG. 3 is a diagram showing emphasis level-noise characteristics.

FIG. 4 is a diagram showing time-output signal characteristics.

[Explanation of symbols]

 10 transmission line 11 feedback transmission line 20 transmission side communication equipment 21 variable pre-emphasis circuit 22 silent signal transmission circuit 23 memory circuit 30 reception side communication equipment 31 variable de-emphasis circuit 32 band pass filter 33 control circuit 331 amplification circuit 332 rectification circuit 333 difference Dynamic amplifier 334 Differentiator circuit 335 Adder circuit 336 DC amplifier circuit 337 Memory circuit

Claims (6)

[Claims] 1. A transmitter side pre-emphasizes an input signal to be sent to a receiver side, sends a pre-emphasized signal to a transmission line, and the receiver side de-emphasis the pre-emphasized signal received from the transmission line. Then, in the transmission device for reproducing an output signal corresponding to the input signal, on the transmission side, a variable pre-emphasis circuit for pre-emphasis the input signal with a variable pre-emphasis characteristic to output the pre-emphasis signal, A silence signal sending circuit for supplying a silence signal to the variable pre-emphasis circuit as the input signal is provided, and the pre-emphasized signal is de-emphasized with a variable de-emphasis characteristic to the reception side to output the output signal. A variable de-emphasis circuit and the silence signal sending circuit are used to input the input signal. As a noise level detecting means for detecting the noise level of the output signal when the silent signal is transmitted, and outputting a detected noise level signal representing the detected noise level, and a noise level based on the detected noise level signal. And a control circuit for determining the pre-emphasis characteristic and the de-emphasis characteristic such that the control signal is provided to the variable de-emphasis circuit, and the control signal is provided to the variable pre-emphasis circuit. In order to achieve this, a transmission device is provided, which is provided with a feedback transmission line for transmitting from the receiving side to the transmitting side. 2. The transmission device according to claim 1, wherein the noise level detecting means is a bandpass filter. 3. The transmission device according to claim 2, wherein the bandpass filter is a filter having an evaluation characteristic according to CCIR Recommendation (468-4). 4. The transmission device according to claim 1, wherein the control circuit time-differentiates the detection noise level signal and outputs the time-differentiated signal as the control signal. 5. A means for fixing the pre-emphasis characteristic of the variable pre-emphasis circuit to a predetermined one when the feedback transmission line is disconnected to the transmitting side, and an alarm signal to the receiving side. And a means for fixing the de-emphasis characteristic of the variable de-emphasis circuit to a predetermined one in response to the alarm signal. 1. The transmission device according to 1. 6. A means for fixing, on the transmitting side, the pre-emphasis characteristic of the variable pre-emphasis circuit to a state before the feedback transmission line is disconnected when the feedback transmission line is disconnected. Means for sending an alarm signal to the receiving side, wherein the de-emphasis characteristic of the variable de-emphasis circuit is fixed to the receiving side in a state before the feedback transmission line is disconnected in response to the alarm signal. The transmission device according to claim 1, further comprising: