JP3133447B2 - Peak hold type modem device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a modem device for digitally modulating a digital signal and outputting the result.

[0002]

2. Description of the Related Art Conventionally, in a radio transmission system using a modem, a digital signal output from a computer terminal 5 is analog-modulated by a modem 6 as shown in FIG. 8 for data transmission.

[0003]

However, in the above-mentioned wireless transmission system, the line quality is deteriorated, and the data transmission speed is increased from the maximum speed (for example, 9600 bps) to 480.
At 0 bps, the modem device sets the average modulation level (modulation level ).
Since the modulation is performed so that the signal average level (Pavr) is constant, the modulated signal MS is as shown in FIG. For this reason, the peak level Pk becomes a value lower than the peak level Pmax of the maximum transmission rate indicated by the broken line portion in FIG. Furthermore, since the error correction method generally retransmits a block in which a bit error is detected, there is a problem that data transmission efficiency is low and data transmission time is long.

An object of the present invention is to improve the demodulation S / N and increase the data transmission efficiency.

[0005]

SUMMARY OF THE INVENTION The problem is that a transmitting section for outputting a modulated signal based on input data so that an average modulation level is constant, a modulated signal from the transmitting section being inputted, and the The problem is solved by a peak hold type AGC circuit that controls the gain so that the value becomes a preset value.

[0006]

The above technical means operates as follows. The transmitting section outputs a modulation signal based on the input data so that the average modulation level becomes constant. The peak hold type AGC circuit receives the modulation signal from the transmission section, and the peak value of the modulation signal is a preset value. The gain is controlled so that In this way, even if the data transmission rate becomes 4800 bps, the peak level of the modulated signal can be made equal to the peak level of the maximum transmission rate, the demodulation S / N can be improved, and the occurrence of bit errors can be reduced. .

[0007]

Embodiments of the present invention will be described below in detail with reference to the drawings. Figure 1 shows an embodiment diagram of the present invention, co when FIG. 2 (a) data transmission rate of 9600bps
Shows the emission stearyl configuration, FIG. 2 (b) shows the analog modulation waveform at that time. FIG. 3A shows that the data transmission speed is 4
FIG. 3 shows a constellation at 800 bps.
(B) shows the analog modulation waveform at that time. FIG. 4 shows an operation explanatory diagram.

First, a configuration example will be described. In FIG. 1, 1 is a computer terminal for outputting a digital signal, 2 is a peak hold type modem device for analogly modulating and outputting a digital signal, and 3 is a peak hold type modem device. 2
Is a single type FM radio that FM-modulates the signal output from the CDMA and demodulates a signal transmitted from the other party. Reference numeral 4 denotes an antenna connected to the single type FM radio 3.

[0009] The peak hold type modem device 2 transmits data via a wired line, and a modem unit 2A, a peak hold type AGC circuit 2B for controlling a gain so that a peak value becomes a preset Pmax, and a peak line AGC circuit 2B. Transmission unit 2 in case
A switch 2C for selecting a signal output from the peak hold type AGC circuit 2B when selecting a signal output from the A-1 and transmitting data through a wireless line;
An amplifier circuit 2D that amplifies the level so as to match the input of the M radio 3 and an amplifier circuit 2E that amplifies the level so as to match the input of the modem unit 2A are provided.

The modem section 2A has a transmitting section 2A-1, a receiving section 2A-2, and a control section 2A-3. Transmission unit 2A-
Numeral 1 analog-modulates the digital signal output from the computer terminal 1 so that the average modulation level Pavr becomes constant, and outputs the result. For example, the data transmission speed is 9600 bps
, The constellation 1 shown in FIG.
Quadrature amplitude modulation is performed at the six points, and an analog modulated waveform shown in FIG. 2B is output. The data transmission speed is 480
At 0 bps, phase modulation is performed at four points of the constellation shown in FIG. 3A, and the result is output as an analog modulation waveform shown in FIG. The receiving unit 2A-2 demodulates the analog modulated signal output from the single type FM radio 3 and converts it into a digital signal. The control unit 2A-3 is a control unit that controls the entire system, a line setting process for connecting a line with a partner before data transmission, a fallback process for determining a data transmission speed according to a line quality situation, and a single type FM radio. Processing such as switching between transmission and reception of the device 3 is performed.

Next, the operation will be described in detail. Before data transmission by the computer terminal 1, the control unit 2A-3 instructs the transmission unit 2A-1 to output a signal for line setting. Thereby, transmitting section 2A-1 performs analog modulation of the signal for line setting and outputs the signal. The analog modulated signal is input to the peak hold type AGC circuit 2B,
Here, the gain is controlled by a preset gain, and the single type FM is controlled.
The signal is input to the wireless device 3 and transmitted to the other party via the antenna 4.

Next, a line setting permission signal sent from the other party is demodulated by the single type FM radio via the antenna 4 and then amplified by the amplifier circuit 2E to be received by the receiver 2A.
-2 to end the line setting process. Next, the control unit 2A
-3 instructs the transmission unit 2A-1 to output a signal for determining the data transmission rate. As a result, the transmission unit 2A-1 performs analog modulation on the signal for determining the data transmission rate and outputs the signal. The analog-modulated signal is input to the peak hold type AGC circuit 2B, where it is controlled with a preset gain, input to the single type FM radio 3 and transmitted to the other party via the antenna 4.

Next, the response signal sent from the other party is demodulated by the single type FM radio 3 via the antenna 4 and then amplified by the amplifier circuit 2E and controlled via the receiver 2A-2. Input to section 2A-3. The control unit 2A-3 analyzes the response signal, determines how much a bit error occurs in the data transmission rate determination signal, and determines the data transmission rate based on the result. Thereafter, the control unit 2A-3
Inputs a transmission rate and a transmission permission signal to the transmission unit 2A-1, and transmission becomes possible.

When the data transmission rate is determined to be 9600 bps, the transmitting section 2A-1 performs analog modulation on the digital signal output from the computer terminal 1 in accordance with FIG. 2 and outputs it to the peak hold type AGC circuit 2B. At this time, since the data transmission speed is the maximum speed, the peak value is Pmax, so that the peak hold type AGC circuit 2B does not change the gain.

On the other hand, when the data transmission rate is determined to be 4800 bps, the transmitting section 2A-1 performs analog modulation on the digital signal output from the computer terminal 1 in accordance with FIG. 3 and outputs it to the peak hold type AGC circuit 2B. In this case, the modulation signal has an analog waveform shown in FIG. Since the output average modulation level Pavr of the transmission unit 2A-1 is constant, the peak value Pk of the analog modulation signal of 4800 bps is
The value is lower than the peak level Pmax of the maximum speed, which is a broken line portion. Therefore, the peak hold type AGC circuit 2
B controls the gain so that the peak value of the analog modulation signal becomes Pmax. As a result, the peak hold type AG
The output of the C circuit 2B has an analog waveform shown in FIG. 4B, and the peak level is equal to the peak level at the highest speed. Thereafter, the signal is FM-modulated by the single type FM radio 3 and transmitted to the other party.

Since the modulation level increases, the demodulation S / N
And data transmission time can be reduced.

[0017]

As has been described in the foregoing, according to the present invention, the data transmission rate determined according to the condition of the line, based on the input data so that the average modulation level becomes constant linear
A transmitting unit that outputs an alternating amplitude modulation signal;
A peak hold type AG that receives a quadrature amplitude modulation signal and controls the gain so that the peak value becomes a preset value.
Since the C circuit is included in the modem device, the quadrature amplitude modulation method
The data transmission rate is changed by the equation, and the quadrature amplitude is
Even if the peak value of the modulated signal changes, set the peak value to the set value.
Can be controlled to be equal to As a result,
Improved demodulation S / N even when data transmission speed is low
And data transmission efficiency can be improved.
Also, according to the present invention, the gain is
It can be controlled with a simple configuration.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of one embodiment of the present invention.

FIG. 2 is an eye pattern and an analog modulation waveform diagram when the data transmission speed is 9600 bps.

FIG. 3 is an eye pattern and an analog modulation waveform diagram when a data transmission rate is 4800 bps.

4A and 4B are a waveform diagram input to a peak hold type AGC circuit and a waveform diagram output therefrom.

FIG. 5 is an example of a conventional configuration.

FIG. 6 is a conventional analog modulation waveform diagram.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Computer terminal 2 ... Peak hold type modem device 2A ... Modem part 2A-1 ... Transmission part 2A-2 ... Reception part 2A-3 ... Control part 2B ... Peak hold type AGC circuit 2C ... Switch 2D ... Amplifier circuit 2E ... Amplifier circuit 3. Single FM radio 4. Antenna

Claims (1)

(57) [Claims] 1. A modem device for analog-modulating and outputting a digital signal, wherein a data transmission rate is determined in accordance with a line condition, and a quadrature amplitude modulation signal is determined based on input data so that an average modulation level is constant. A peak-to-peak AGC circuit that receives a quadrature amplitude modulation signal from the transmitter and controls the gain so that the peak value becomes a preset value. Hold type modem device.