JPH02145057A - Modulator-demodulator - Google Patents

Abstract

PURPOSE:To make an average signal power on a telephone line independent of the modulation system and to reduce a mis-demodulation rate by increasing the gain of a transmission amplifier by nearly 2.55dB in comparison with frequency shift keying (FSK) or 4-phase shift keying (PSK) in the case of the signal modulation system being 16-phase quadrature amplitude modulation (QAM). CONSTITUTION:A transmission data being a digital signal sent to a destination is modulated by a modulation demodulation circuit 11. The modulated digital signal is converted into an analog signal by a D/A converter 6. The transmission data converted into an analog signal from the digital signal is limited to a band specified by a telephone line 1 by a transmission filter 5. When the modulation system is the 16-phase QAM, the modulation/demodulation circuit 11 uses a 16-phase QAM control signal to inform it to the transmission amplifier 10 that the sent signal is the 16-phase QAM signal. When the 16-phase QAM signal is recognized to be the sent signal by the 16-phase QAM control signal, the voltage gain of the transmission amplifier 10 is increased by nearly 2.55dB more than the FSK or the 4-phase PSK.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to a modulation/demodulation device required when performing data communication using a public line.

2. Description of the Related Art In recent years, with the spread of personal computers and the like, data communication using general public lines is becoming more popular. Accordingly, modems (hereinafter referred to as modems) are rapidly becoming popular.

A conventional modem will be explained below.

FIG. 2 is a block diagram of a conventional modem.

In FIG. 2, a public line (hereinafter referred to as a telephone line) is shown.

) 1 is received by the 2-wire/4-wire conversion circuit 2 together with the input from the transmitting amplifier 3, and the output is sent to the receiving filter 4. The output filter 5 limits the band of the output of the DA converter 6 and outputs it to the output amplifier 3. The modulation/demodulation circuit 7 outputs the modulated digital data to the DA converter 6 and modulates the output of the AD converter 8. AG
At C8, the output of the reception filter 4 is amplified and made into a signal with a size suitable for the input range of the AD converter 8.

Describing the transmission operation of this modulation/demodulation device, first, the transmission data of the digital signal sent to the destination is modulated by the modulation/demodulation circuit 7. The modulated digital signal is
A converter 6 converts it into an analog signal. Transmission data converted from digital to analog signals is limited by a transmission filter 5 to a band specified by the regulations of the telephone line 1. The transmission data whose band is limited is sent to the transmission amplifier 3.
After the magnitude of the signal is adjusted, it is placed on the telephone line 1 via the 2-wire/4-wire conversion circuit 2 and sent to the other party.

Next, the reception operation will be explained. Received data sent from the other party is input from a telephone line 1 to a reception filter 4 via a 2-wire and 4-wire conversion circuit 2. The received data is
The reception filter 4 limits the band to only the band necessary for demodulating the received data. Thereafter, the AGC 9 adjusts the size, and the AD converter 8 converts the analog signal into a digital signal. The received signal, which has become a digital signal, is demodulated by a modulation/demodulation circuit 7, and received data is extracted.

Here, the modulation method will be described. The modulation method depends on the communication speed and communication method, such as CCITT standard or Be
It is defined by the 1l standard. Communication speed is BP
It is expressed as S (Bit Per 5 seconds). The communication method refers to either half-duplex or full-duplex. Half-duplex means one-way communication, and when the other party is sending data, the communication method is half-duplex or full-duplex. When you are sending data, the other party cannot send data. Full duplex refers to bidirectional communication, which allows data to be sent to both parties at the same time.

The 2400 BPS full duplex modem uses frequency modulation (Freq
uency 5hift keying: Below,
It is called FSK. ) and four-phase phase modulation (Phase
ShiftKeying: Hereinafter referred to as 4-phase PSK. ) and 16-phase quadrature amplitude modulation (Quadrature
Amplitude Modulation: Below,
It is called 16-phase QAM. ) has three modulation methods. FSK is used for communication speed of 300 BPS, 4
Phase PSK is used for communication speed of 1200BPS,
16-phase QAM is used for communication speeds of 2400 BPS.

The average signal power of FSK and 4-phase PSK is approximately 2.55 dB of the average signal power of a 16-phase QAM signal with the same peak value.
known to be large. In other words, when comparing the average signal power of a 16-phase QAM signal with the same peak value, an FSK signal, and a 4-phase PSK signal, the 16-phase QAM signal has approximately 2.55
dB small.

Problems that the invention aims to solve However, in the above conventional configuration, FSK.

The modulated signals of 4-phase PSK and 16-phase QAM are sent to the telephone line so that their peak values are equal. Therefore, only the 16-phase QAM signal has an average signal power of about 2.
This has the drawback that the signal-to-noise level ratio (hereinafter referred to as S/N) when received by the other party's modem decreases by 55 dB, which may cause erroneous demodulation of the 16-phase QAM signal. Was.

The present invention solves the above-mentioned conventional problems.
, 4-phase PSK, and 16-phase QAM modulation methods, and eliminate the difference in average signal power on a telephone line, thereby reducing erroneous demodulation on the receiving side.

Means for Solving the Problems To achieve this object, the modem of the present invention has a voltage gain of 16-phase QAM signals, FSK, 4-phase PSK,
It has a transmitting amplifier that increases by about 2.55 dB compared to the previous model.

Effect: With this configuration, the average signal power sent to the telephone line can be made equal for the 16-phase QAM signal, the FSK signal, and the 4-phase PSK signal.

EXAMPLES Hereinafter, examples of the present invention will be described with reference to the drawings.

FIG. 1 shows a block diagram of a modem in an embodiment of the present invention. In Figure 1, ■ is a telephone line, 2
is a two-wire and four-wire conversion circuit, 4 is a reception filter, 5 is a transmission filter, 6 is a DA converter, and 10 is a modulation/demodulation circuit.

The modulation/demodulation circuit 10 converts the modulated digital data into D
It outputs to the A converter 6 and demodulates the output of the AD converter 8. The AGC 9 amplifies the output of the reception filter 4 and converts it into a signal with a size suitable for the input range of the AD converter 8. The 16-phase QAM control signal is output from the modulation/demodulation circuit 11 to the transmission amplifier 10 via the signal line 12.

First, the transmission operation will be explained. The transmission data of the digital signal sent to the destination is modulated by the modulation/demodulation circuit 11 . The DA converter 6 converts the modulated digital signal into an analog signal.

Transmission data converted from digital to analog signals is limited by a transmission filter 5 to a band specified by the regulations of the telephone line 1. The band-limited transmission data is sent out onto the telephone line 1 via the 2-wire/4-wire conversion circuit 2 after its signal size is adjusted by the sending amplifier 10 .

When the modulation method of the modulation/demodulation circuit 11 is 16-phase QAM,
The 16-phase QAM control signal is used to notify the sending amplifier 10 that the signal to be sent is a 16-phase QAM signal. Due to the 16-phase QAM control signal, the signal to be sent is 16
Knowing that it is a phase QAM signal, the sending amplifier 10 increases the voltage gain by approximately 2.5 compared to the case of FSK and 4-phase PSK.
Increase by 5dB. The average signal power of the signal sent to the telephone line 1 does not depend on the modulation method.

The reception operation is the same as the conventional example.

As described above, according to this embodiment, when the modulation method of the transmission signal is 16-phase QAM, the voltage gain of the transmission amplifier is
In the case of FSK and 4-phase PSK, by increasing the signal power by about 2.55 dB, the average signal power of the transmitted signal on the telephone line becomes independent of the modulation method, and erroneous demodulation can be reduced.

Effects of the Invention As described above, according to the present invention, the gain of the transmitting amplifier is
When the signal modulation method is 16-phase QAM, FSK, 4
By increasing the signal power by about 2.55 dB compared to phase PSK, it is possible to realize an excellent modulation/demodulation device that can make the average signal power on the telephone line independent of the modulation method and reduce the error demodulation rate.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of a modulation/demodulation device according to an embodiment of the present invention, and FIG. 2 is a block diagram of a conventional modulation/demodulation device. 1...Public line, 2...2-wire 4-wire conversion circuit, 4...Receiving filter, 5...Outgoing filter, 6...・DA converter, 8...
...AD converter, 9...AGCllo・
... Sending amplifier, 11 ... Modulation/demodulation circuit,
12...16-phase QAM control signal line.

Claims (1)

[Claims] For modulation/demodulation circuits for frequency modulation, 4-phase phase modulation, and 16-phase quadrature amplitude modulation, and only for 16-phase quadrature amplitude modulation, the voltage amplification factor is increased to equalize the average signal power on general public lines. A modem device equipped with a transmitting amplifier.