JPH1146178A - Spread spectrum pulse position modulation communication system and transmitter-receiver used in the system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate a spread modulation signal and to accelerate the transmission speed more even when adjacent pseudo-spread sequences overlap each other by coping with the situation by using the value of the sum of both of them when the overlapping of a pseudo noise sequence of a frame and the pseudo noise sequences preceding and succeeding it. SOLUTION: First, data to be transmitted is performed pulse position modulation by a PPM modulator 1. A pulse position modulation signal is alternately separated into two by a pulse separating circuit 2 and inputted to pseudo noise generators 3 and 4. The generators 3 and 4 generate pseudo noise sequences with an inputted pulse as a trigger. Outputs from the generators 3 and 4 are added by an adder 5, and a spread signal to be transmitted is generated. When a pseudo noise sequence of a certain frame overlaps the pseudo noise sequence preceding or succeeding it in a certain slot at the time of transmission, the sum of both is used as the value of the slot. This makes it possible to improve data transmission density.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spread spectrum pulse position modulation communication system and a transmitter / receiver used in the system, and is suitably applied to, for example, indoor wireless communication, wireless LAN, wireless high-speed data communication, and the like. Things.

[0002]

2. Description of the Related Art Japanese Unexamined Patent Publication No. 4-137835 (spread spectrum pulse position modulation communication system) has been proposed as a system capable of high-speed data transmission within a limited band with respect to a spread spectrum communication system. . The invention described in this publication uses a pseudo-noise sequence for one period instead of the pulse of the pulse position modulation signal. The speed is higher than that of the direct spreading method in which the next modulated wave is multiplied by a periodic pseudo-noise sequence. The invention of Japanese Patent Application Laid-Open No. 4-113732 (spread spectrum pulse position modulation communication system) is an invention including the basic concept of the spread spectrum pulse position modulation communication system. A slot (pseudo noise sequence) is used.

FIG. 8 is a diagram for explaining a conventional spread spectrum pulse position modulation communication system (Japanese Patent Laid-Open No. 4-137835). In the prior art, a data symbol to be transmitted is represented by M, and a period of a pseudo noise sequence is represented by M. Assuming that one frame is M + L-1 + j (where 0 ≦ j), it is assumed that no signal overlaps with the adjacent frame. The invention described in JP-A-4-137835 (spread spectrum pulse position modulation communication system) improves the invention described in JP-A-4-113732, which is an invention including the basic idea of the present invention, By performing differential coding on transmission data, synchronization pulses are deleted, thereby achieving higher speed. However, it is assumed that adjacent spreading sequences do not overlap.

[0004] Further, the applicant of the present invention discloses a method disclosed in Japanese Patent Laid-Open No. 4-137.
No. 835, the pseudo-noise sequence and the inverted sequence whose polarity is inverted are used in combination with the spread modulation to reduce the transmission rate by 2
Proposed the invention twice as fast (Japanese Patent Application No. 8-21).
No. 1641). However, this Japanese Patent Application No. Hei 8-2116
The invention of No. 41 is based on the premise that adjacent spreading sequences do not overlap.

Further, the present applicant has proposed a "spread spectrum pulse position modulation communication system" which is an improvement of the above-mentioned patent application (Japanese Patent Application No. 8-21641). That is,
Higher speed was achieved by mounting different modulation signals on mutually orthogonal carriers. However, the present invention is based on the premise that adjacent spreading sequences do not overlap.

[0006]

SUMMARY OF THE INVENTION Accordingly, Japanese Patent Application No. Hei.
In the invention described in JP-A-211641, it is assumed that the length of one frame for transmitting information is equal to or longer than the sum of the information slot and the sequence length of the pseudo-noise sequence. Besides, there is a disadvantage that an extra length of the spreading sequence is required.
However, if the length of one frame is made equal to or less than the sum of the information slot and the sequence length of the pseudo noise sequence, there is a possibility that adjacent pseudo noise sequences may overlap. It is possible. That is, even if the length of one frame is shortened, information can be transmitted, thereby increasing the information density and increasing the transmission speed.

The present invention has been made in view of the above situation, and separates a pulse position modulation signal for generating a spread sequence into two, and converts these two pulse position modulation signals into two pseudo noise sequence generation circuits. To generate two spread modulation signals, and by adding these two spread modulation signals, it is possible to generate a spread modulation signal even when adjacent pseudo-spread sequences overlap. It is an object of the present invention to provide a spread spectrum communication system capable of further increasing the transmission speed.

[0008]

According to the first aspect of the present invention, a pseudo-noise sequence having a length of L and an M-value data symbol as transmission data are prepared, and the data symbol is differentially encoded as necessary. For each frame composed of a number of slots less than M + L-1, one of the M slots from the beginning of the frame is selected corresponding to the data symbol value M, and the L slots starting from the selected slot are selected. When a pseudo-noise sequence is inserted into a slot to generate one frame signal, and when similar frame signals are successively generated and transmitted sequentially, there is a pseudo-noise sequence of a certain frame and the pseudo-noise sequence thereof. When a slot overlaps, the sum of the two values is used as the value of the slot, whereby the pseudo-noise sequence of the frame and the pseudo-noise sequence of the frames before and after the frame are used. When the overlap of occurs by addressing using the value of the sum of both, as compared with the conventional spread spectrum pulse position modulation communication method, in which so as to enhance the data transmission density.

According to a second aspect of the present invention, in the spread spectrum pulse position modulation communication system according to the first aspect,
A pulse separation circuit that performs pulse position modulation on data to be transmitted and separates the generated pulse position modulation signal into N (N ≧ 2) pulse position modulation signals in sequence; Provision of N pseudo-noise generating circuits for generating a noise sequence, inputting each pseudo-noise generating circuit with each output of the pulse separation circuit as a trigger, and adding the generated N pseudo-noise sequences by an adder A modulated signal is generated, and if necessary, the RF signal is amplified and further frequency-converted and amplified by the RF frequency conversion amplification unit, so that it is used as a transmission signal.Thus, even when a pseudo noise sequence overlaps, , A plurality of pseudo noise generators can be used to generate a spread spectrum pulse position modulation signal. There are various types of conversion to RF, such as simply applying a carrier, or various types of conversion, such as preparing two signals according to claim 2 and modulating them with orthogonal carriers.

According to a third aspect of the present invention, in the spread spectrum pulse position modulation communication system of the first aspect,
An RF frequency conversion amplification unit that receives a signal from the spread spectrum pulse position modulation transmitter according to claim 2, amplifies the received signal as necessary, and converts the signal into an intermediate frequency signal or a baseband signal; A matched filter that generates a pulse position modulation signal by outputting a matched pulse when the same pseudo-noise sequence as the transmitting side is input to a baseband signal, and a peak interval measuring circuit that measures the peak interval of the matched pulse And a data symbol reproducing circuit for reproducing an original data symbol, thereby enabling reception with a configuration almost the same as that of the conventional one, and enabling high-speed data transmission.

According to a fourth aspect of the present invention, in the second aspect of the present invention, the pulse separation circuit for separating the pulse position modulation signal divides a frame pulse, and outputs the divided signal;
The pulse is separated by taking the logical product of the pulse position modulation signal, thereby enabling a circuit for separating the pulse position modulation signal to be realized by a simple circuit.

According to a fifth aspect of the present invention, there is provided a pseudo-noise sequence having a length L, an inverted sequence obtained by inverting the sign of the pseudo-noise sequence, and two data symbols to be transmitted. The position modulation signals P1 and P2 are generated, and P1
A spread signal is obtained by the spread spectrum pulse position modulation transmitter according to claim 2 using the pseudo noise sequence with respect to
2. A spread spectrum signal obtained by the spread spectrum pulse position modulation transmitter according to claim 2 using the inverted sequence with respect to 2 and adding them by an adder to obtain a baseband modulation signal. One pseudo-noise sequence and its inverse sequence are used for modulation, and spread-spectrum pulse position modulation can be performed on each of them, and further, on each of them,
The data transmission density can be increased to enable high-speed data transmission.

According to a sixth aspect of the present invention, a pseudo noise sequence having a length L, an inverted sequence obtained by inverting the sign thereof, and four data symbols to be transmitted are prepared, and pulse position modulation is performed on each of the data symbols. A position modulation signal P1, P2, P3, P4 is generated, and a modulation signal is generated for P1 and P2 by the spread spectrum pulse position modulator according to claim 5, and this is expressed by I
As a baseband signal of the channel, similarly, P3
A modulated signal is generated for P4 by the spread spectrum pulse position modulator according to claim 5, which is used as a baseband signal of a Q channel, a carrier having a phase difference of 90 degrees is prepared, and one of the modulated signals is used for an I channel. Since the signal is multiplied by the baseband signal, the other is multiplied by the baseband signal of the Q channel, and finally the two signals are added and the quadrature-modulated signal is transmitted as a transmission signal, one pseudo noise is added to the spread modulation. Spread spectrum pulse position modulation can be performed on each of two orthogonal carriers using a sequence and its inverted sequence, and the data density can be increased for each of them, enabling high-speed data transmission. It was done.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION

(Invention of Claim 1) FIG. 1 is a diagram showing a basic frame configuration in the present invention. In the present invention, it is assumed that an overlap with a signal of an adjacent frame occurs. Consider the case where the number of information bits is M and the period of the pseudo-noise sequence is L, and the length of one frame is less than M + L-1. In FIG. 1, FIG. 1 (A) shows the pseudo noise sequence for each frame separately, and FIG.
The figure shows a case where data symbols 0 and 2 or differentially encoded data symbols are transmitted. FIG. 1B shows the result of adding the signals of frame 1 to frame 4, and the transmitted spread signal overlaps the pseudo-noise sequence of the adjacent frame. The receiver can generate a matched pulse by passing this spread signal through a matched filter that matches the pseudo-noise sequence on the transmitting side, and can reproduce the pulse position modulated wave before spread modulation. It is.

(Invention of Claim 2) FIG. 2 relates to the invention of claim 2, that is, relates to a transmitter for generating a spread signal in which pseudo noise sequences overlap as described above. This is an example of the case of separation into two, and will be described below with reference to FIG. The transmitted data is first subjected to pulse position modulation by the PPM modulator 1. The pulse position modulation signal is alternately output to 2 by the pulse separation circuit 2.
And they are input to different pseudo noise generators 3 and 4, respectively. The pseudo noise generator generates a pseudo noise sequence using the input pulse as a trigger. Outputs from the two pseudo noise generators are added by an adder 5 to generate a spread signal to be transmitted.

(Invention of claim 3) FIG. 3 is a block diagram for explaining the invention of claim 3, and the invention of claim 3 performs the spread spectrum pulse position modulation transmission of claim 2 as described above. The present invention relates to a spread spectrum pulse position modulation receiver that receives a spread signal transmitted from a receiver and reproduces the original transmitted data. The received signal is amplified by an amplifier 11 and then by a multiplier 12. After being multiplied by a signal from the local oscillator 13 and frequency-converted into a baseband or IF signal, a BPF (bandpass filter) 1
4. The signal is input to a matched filter 16 through an AGC (automatic gain control circuit) 15. The matched filter 16 generates a matched pulse when a sequence that matches the pseudo noise sequence of the transmitter is input. The matched pulse is converted into a pulse position modulation signal by passing through the peak detection circuit 17. The pulse interval of this signal is measured by the pulse interval measuring circuit 18 and then input to the data reproducing circuit 19 to reproduce the original data.

(Invention of claim 4) FIG. 4 is a view for explaining the invention of claim 4, and the invention of claim 4 is based on claim 2.
4 relates to a pulse separation circuit for separating a pulse position modulation signal in the spread spectrum pulse position modulation transmitter of FIG. 1. FIG. 4 shows the function of the pulse separation circuit 2 shown in FIG. This is an example of the case. The input pulse position modulation signal (FIG. 4A) is separated into two at the timing of a frame, and as a result, two pulse position modulation signals (a pulse position modulation signal exist every other frame). FIG.
(B ₁ ) and (B ₂ )).

FIG. 5 is a diagram showing an example of a circuit configuration for realizing the separation of the pulse position modulation signal as described above. The pulse position modulation signal wave (PPM signal) and the frame clock pulse are supplied to the D flip-flop 23 and Inverter 24
Are multiplied by AND circuits 21 and 22 to obtain two pulse position modulation signals PPM1,
It is separated into PPM2. PPM1 and PPM2 are each input to the pseudo noise generator.

(Invention of Claim 5) FIG. 6 is a diagram for explaining the invention of claim 5, wherein the invention of claim 5 uses a pseudo noise sequence and an inverted sequence whose sign is inverted. The pseudo-noise sequence generator and the inverted sequence generator of the spread spectrum pulse position modulator use the spread spectrum pulse position modulation transmitter described in claim 2. In FIG. 6, data to be transmitted is a serial / parallel converter 31.
, The data is divided into two parallel data symbols. This data symbol is supplied to each of the pulse position modulators 32A and 32A.
Pulse position modulation is performed by 2B, and P1, P1, respectively.
It is converted to a pulse position modulated wave of P2. About P1
As described with reference to FIG. 2, the spread spectrum pulse position modulator (pulse separation circuit 34A, PN signal generators 34A ₁ , 3
4A ₂ , the spread spectrum pulse position modulation signal PN1 is obtained by the adder 35A). Regarding P2, an inverted sequence obtained by inverting the sign of the pseudo-noise sequence used in P1 (pulse separation circuit 33B, inverted PN signal generation circuits 34B ₁ , 34)
B ₂ , an inverted spread spectrum pulse position modulation signal PN ₂ is obtained by using the adder 35B), and PN ₁ and the inverted PN ₂ are added by the adder 36 to generate a base band spread spectrum pulse position modulated signal. .

FIG. 7 is a block diagram for explaining the invention of claim 6, wherein the data to be transmitted is converted into four parallel data symbols by a serial / parallel converter 41. PPM modulator 42A ₁ ,
Pulse position modulation is performed by 42A ₂ , 42B ₁ , and 42B ₂ to generate pulse position modulated waves P1, P2, P3, and P4. For P1 and P2, as in FIG. 6, the pseudo noise sequence of length L (43A ₁ , 44A ₁₁ , 44A ₁₂ , 45A ₁ )
It was used to generate a spread spectrum pulse position modulated signal PN ₁ in the manner described in FIG. 2, further the inverting sequence of pseudo-noise sequence _{(43A 2, 44A 21, 44A} 22, 45A 2) with inverted PN ₂ Generate The result of addition by the adder 46A the PN ₁ and the inverted PN _2, the baseband signal of I channel. Similarly for P3 and P4, 43B
_{1, 44B 11, 44B 12,} 45B 1 and 43B _2, 44B
_21, 44B _22, 45B ₂ was used to produce a speckle spread pulse position modulated signal PN ₃ and the inverted PN _4, adds at their adder 46B, the resulting baseband signal Q channel. Local oscillator 48 and 90-degree phase shifter 49
Are prepared and carrier waves having a phase difference of 90 degrees from each other are generated,
The multipliers 47A and 47B respectively multiply the baseband signals of the I channel and the Q channel, and add them by an adder 50 to obtain a transmission signal.

[0021]

According to the first aspect of the present invention, a pseudo-noise sequence having a length of L and an M-value data symbol as transmission data are prepared.
The data symbols are differentially encoded as needed, and M +
For each frame composed of a number of slots less than L-1, one of the M slots from the beginning of the frame is selected corresponding to the data symbol value M, and the L slots starting from the selected slot are selected. When a pseudo-noise sequence is inserted into a slot to generate one frame signal, and a similar frame signal is successively generated and transmitted, there is a pseudo-noise sequence of a certain frame and pseudo-noise sequences before and after the certain frame. When the slots overlap, the sum of the two is used as the value of the slot, so that the data transmission density can be improved as compared with the conventional spread spectrum pulse position modulation communication system.

According to a second aspect of the present invention, in the spread spectrum pulse position modulation communication system of the first aspect,
A pulse separation circuit that performs pulse position modulation on data to be transmitted and separates the generated pulse position modulation signal into N (N ≧ 2) pulse position modulation signals in sequence; N pseudo noise generation circuits for generating a noise sequence are prepared, and each output of the pulse separation circuit is used as a trigger and input to each pseudo noise generation circuit.
Since the modulated signal is generated by adding the pseudo-noise sequences by an adder, and if necessary, the modulated signal is further frequency-converted and amplified by an RF frequency conversion amplifying unit so as to become a transmission signal. Even when a pseudo noise sequence is generated, a plurality of pseudo noise generators can be used to generate a spread spectrum pulse position modulation signal.

According to a third aspect of the present invention, in the spread spectrum pulse position modulation communication system according to the first aspect,
Receiving a signal from the spread spectrum pulse position modulation transmitter described in claim 2, amplifying the received signal as necessary,
RF to convert to intermediate frequency signal or baseband signal
A frequency conversion amplifier, a matched filter that outputs a matched pulse to the intermediate frequency signal or the baseband signal when the same pseudo noise sequence is input to the transmitting side and generates a pulse position modulation signal, and a matched filter. Since it has a peak interval measurement circuit that measures the pulse peak interval and a data symbol regeneration circuit that regenerates the original data symbol, reception is possible with almost the same configuration as before, enabling high-speed data transmission. Become.

According to a fourth aspect of the present invention, in the second aspect of the present invention, the pulse separation circuit for separating the pulse position modulation signal divides a frame pulse and outputs the divided signal;
Since the pulse is separated by taking the logical product of the pulse position modulation signal, a circuit for separating the pulse position modulation signal can be realized with a simple circuit.

According to a fifth aspect of the present invention, a pseudo noise sequence having a length L, an inverted sequence obtained by inverting the sign thereof, and two data symbols to be transmitted are prepared, and pulse position modulation is performed on each of the data symbols. The position modulation signals P1 and P2 are generated, and P1
A spread signal is obtained by the spread spectrum pulse position modulation transmitter according to claim 2 using the pseudo noise sequence with respect to
2 to obtain a baseband modulation signal by obtaining a spread signal by the spread spectrum pulse position modulation transmitter according to claim 2 using the inverted sequence and adding them by an adder. Using one pseudo-noise sequence and its inverse sequence, and performing spread spectrum pulse position modulation on each of them, and further increasing the data transmission density for each of them, high-speed data transmission becomes possible. .

According to a sixth aspect of the present invention, there is provided a pseudo-noise sequence having a length L, an inverted sequence obtained by inverting the sign of the pseudo-noise sequence, and four data symbols to be transmitted. Position modulation signals P1, P2, P3, and P4 are generated, and a modulation signal is generated for P1 and P2 by a spread spectrum pulse position modulator, which is used as an I-channel baseband signal. , A modulated signal is generated by a spread spectrum pulse position modulator, this is used as a Q channel baseband signal, carrier waves having a phase difference of 90 degrees are prepared, and one is multiplied by an I channel baseband signal. And the other is multiplied by the baseband signal of the Q channel, and finally, the two signals are added and the orthogonally modulated signal is transmitted as a transmission signal, so that data transmission is performed. One pseudo-noise sequence and its inverse sequence are used for spread modulation, and further, spread-spectrum pulse position modulation can be performed on each of two orthogonal carriers, and the data density can be increased for each of them. Data transmission becomes possible.

[Brief description of the drawings]

FIG. 1 is a diagram showing a basic frame configuration in the present invention.

FIG. 2 is a diagram illustrating an example of the invention of claim 2, that is, an example of a transmitter that generates a spread signal in which pseudo noise sequences overlap.

FIG. 3 is a diagram for explaining an example of a third embodiment, that is, an example of a spread spectrum pulse position modulation receiver.

FIG. 4 is a diagram for explaining the invention of claim 4, that is, pulse separation.

FIG. 5 is a diagram illustrating an example of a circuit configuration for describing an example of a pulse separation circuit.

FIG. 6 is a diagram for explaining an example of the invention of claim 5;

FIG. 7 is a diagram for explaining an example of the invention of claim 6;

FIG. 8 is a diagram illustrating an example of a conventional frame configuration.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... PPM modulator, 2 ... Pulse separation circuit, 3,4 ... Pseudo noise generator, 5 ... Adder, 11 ... Amplifier, 12 ... Multiplier, 13 ... Local oscillator, 14 ... BPF (bandpass filter), 15 ... AGC (automatic gain control circuit), 16 ... matched filter, 17 ... peak detection circuit, 18 ... pulse interval measuring circuit, 19 ... data reproducing circuit, 31, 41 ... a serial-parallel converter, 32A, 32B, 42A _1, 4
2A ₂ , 42B ₁ , 42B ₂ ... PPM modulator, 33A, 3
_{3B, 43A 1, 43A 2,} 43B 1, 43B 2 ... pulse separation _{circuit, 34A 1, 34A 2, 34B} 1, 34B 2, 44A
_{11, 44A 12, 44A 21,} 44A 22, 44B 11, 44B
_{12, 44B 21, 44 22 ...} PN signal generator, 45A _1, 4
5A ₂ , 45B ₁ , 45B ₂ , 46A, 46B, 50 ... adder, 47A, 47B ... multiplier, 48 ... local oscillator, 4
9 ... Phase shifter.

Claims (6)

[Claims] 1. A pseudo-noise sequence having a length L and an M-value data symbol as transmission data are prepared, and the data symbol is differentially encoded as necessary, and is composed of a number of slots less than M + L-1. For each frame, one of the M slots from the beginning of the frame is selected corresponding to the data symbol value M, and L starting from the selected slot is selected.
In one slot, the pseudo-noise sequence is inserted to generate one frame signal, and when a similar frame signal is continuously generated and transmitted, the pseudo-noise sequence of a certain frame and the pseudo-noise sequences before and after the frame are generated. A spread spectrum pulse position modulation communication system characterized in that when a certain slot is overlapped, a value of the sum of the two is used as the value of the slot. 2. A transmitter for use in the spread spectrum pulse position modulation communication system according to claim 1, wherein the transmitter performs pulse position modulation on data to be transmitted.
A pulse separation circuit that sequentially separates the generated pulse position modulation signal into N (N ≧ 2) pulse position modulation signals, and N pseudo noise generation circuits that receive a trigger pulse and generate a pseudo noise sequence Prepared, each output of the pulse separation circuit as a trigger, input to each pseudo-noise generation circuit, add the generated N pseudo-noise sequences by an adder, generate a modulation signal, and if necessary, RF A spread spectrum pulse position modulation transmitter characterized in that the modulated signal is further frequency-converted and amplified by a frequency conversion amplifier to obtain a transmission signal. 3. A spread spectrum pulse position modulation communication system according to claim 1, wherein the receiver receives a signal from the spread spectrum pulse position modulation transmitter according to claim 2, amplifies the received signal as necessary, An RF frequency conversion amplifying unit that converts the signal into an intermediate frequency signal or a baseband signal, and outputs a matched pulse when the same pseudo noise sequence as that on the transmission side is input to the intermediate frequency signal or the baseband signal; A spread spectrum pulse position modulation receiver comprising a matched filter for generating a position modulation signal, a peak interval measuring circuit for measuring a peak interval of a matched pulse, and a data symbol reproducing circuit for reproducing an original data symbol. . 4. A pulse separation circuit for separating said pulse position modulation signal, divides the frame pulse, and separates the pulse by taking the logical product of the divided signal and the pulse position modulation signal. 3. The spread spectrum pulse position modulation transmitter according to claim 2, wherein: 5. A pseudo-noise sequence having a length L, an inverted sequence obtained by inverting the sign of the pseudo-noise sequence, and two data symbols to be transmitted are prepared, and pulse position modulation is performed on each of them. 3. A spread spectrum signal according to claim 2, wherein P2 is generated, a spread signal is obtained by the spread spectrum pulse position modulation transmitter according to claim 2, using the pseudo noise sequence for P1, and the inverted sequence is used for P2. A spread spectrum pulse position modulator characterized in that a spread signal is obtained by a pulse position modulation transmitter, and these are added by an adder to obtain a baseband modulated signal. 6. A pseudo-noise sequence having a length L, an inverted sequence obtained by inverting the sign of the pseudo-noise sequence, and four data symbols to be transmitted are prepared, and pulse position modulation is performed on each of them. P2, P3, and P4 are generated, and P1, P
2, a modulated signal is generated by the spread spectrum pulse position modulator according to claim 5, which is used as an I-channel baseband signal. Similarly, the spread spectrum pulse position according to claim 5 is applied to P3 and P4. A modulated signal is generated by a modulator, this is used as a Q-channel baseband signal, carrier waves having a phase difference of 90 degrees are prepared, one is multiplied by an I-channel baseband signal, and the other is multiplied by a Q-channel A spread-spectrum pulse position modulation communication method characterized in that data is transmitted as a transmission signal by multiplying a baseband signal, and finally adding the two and quadrature-modulating the transmission signal.