JPH07333324A - Longest linear code series generating circuit - Google Patents

Abstract

PURPOSE:To enhance the secrecy by outputting an initial value, corresponding to the length of M code (longest linear code series), arbitrarily from an M code initial value generating circuit and varying the phase modulation pattern of a transmission wave thereby spreading the transmission wave over a wider band. CONSTITUTION:A transmission timing generating section 5 receives a signal from a counter 4 and generates a gate corresponding to the transmission pulse width. An code length data of M code is fed through a bus transceiver 1 to an M code coefficient latch 6 thence to an M code generating section 7. Every time when an M code modification signal is received, an M code initial value generating section 9 delivers the initial value of M code, corresponding to the code length, arbitrarily to an M code generating section 7. Since the phase modulation pattern of transmission wave is varied as compared with the case where the initial value is constant, the spectral pattern of transmission wave is varied and the secrecy is enhanced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a longest linear code sequence (hereinafter abbreviated as M code) generation circuit used for modulation of a transmission wave in a spread spectrum radar.

[0002]

2. Description of the Related Art FIG. 5 is a diagram showing a configuration of a conventional M code generation circuit. In the figure, 1 is a bus transceiver for reading data from a signal processor, 2 is a pulse width latch for latching and outputting pulse width data from the bus transceiver 1, and 3 is a bus
A register for latching and outputting data from the transceiver 1, a counter 4 for counting the data from the register 3 as an initial value, and a counter for outputting a part of the count value to a transmission timing generator, and a reference numeral 5 for an output signal of the counter 4. A transmission timing generator for generating a transmission pulse gate, 6 is an M code coefficient latch for latching and outputting M code code length data from the bus transceiver 1, and 7 is an M code every time an M code change signal is input. An M code generator that sets and outputs an M code based on the M code code length data from the coefficient latch 6 and the M code initial value, and 8 is an AND of the output of the transmission timing generator 5 and the output of the M code generator 7.
Is an AND gate that outputs a modulated signal.

Next, the operation will be described. The pulse width data input from the signal processor is the bus transceiver 1
Is output to the pulse width latch 2 via. The data input to the pulse width latch 2 is output to the register 3 by the pulse width control signal. The register 3 sends data to the counter 4 in response to the pulse width change signal. Counter 4
Upon receiving this data, starts counting at each clock and outputs a part of the count value to the transmission timing generator 5. The transmission timing generator 5 generates a gate corresponding to the transmission pulse width according to the received signal. On the other hand, the M code code length data is sent to the M code coefficient latch 6 via the bus transceiver 1 and then to the M code generator 7. The M code generator 7 sets the M code with a constant initial value each time the M code change signal is generated, and outputs a code corresponding to the M code code length. The AND gate 8 ANDs the transmission pulse gate output from the transmission timing generator 5 and the M code output from the M code generator 7 to generate a change signal.

Next, the features of the M code will be described. The M code is called a pseudo-random sequence, and is a digital code sequence that can be generated using an n-stage shift register. The periodicity has a period of (2 ⁿ −1), and the number of appearances of “1” and “0” is 1 in one period.
Only difference.

FIG. 6 shows the configuration of the M code generation circuit (code length 15). The M code generation circuit generates an M code by means of a four-stage shift register and an XOR gate. Now
When the initial value of the shift register (X ₄ , X ₃ , X ₂ , X ₁ ) is set to (0, 0, ₁ , ₁ ), the change in the contents of the shift register at each time is obtained as follows.

[0006]

[Outer 1]

The numbers enclosed by □ are output bits of the shift register, and the sequence of codes formed by arranging them in order is an M code having a code length of 15 cycles. The M code generator circuit
Depending on the code length, the number of stages of the shift register, feedback, tapping positions, and the number of XOR gates are changed.

[0008]

The conventional M code generation circuit is configured as described above, and even if the M code code length changes, the initial value sent to the shift register of the M code generation unit is the M code length, It is fixed regardless of the pulse width, and the code string corresponding to the code length is fixed. For example,
When the pulse width is 720 nsec, the M code code length is 15, the modulation signal has 1 bit in the gate of 80 nsec, and the duty of the output gate of the transmission timing generation unit is 33%, FIG.
According to the above, at the initial value (0,0,0,1), the code string in the gate of the modulated signal is "100010011". When the pulse width is changed from 720 nsec to 320 nsec by the pulse width change signal, the initial value is (0, 0,
Since it is fixed at 0, 1), the code string in the gate of the modulation signal is "1000". FIG. 7 shows the above case. From this, a code string in which the code in the gate of the modulation signal is "0" or "1" depending on the case where the M code having a long code length is set when the transmission pulse width is short and the timing of changing the pulse width. In some cases, the spreadability of the transmitted wave is reduced, and the confidentiality may be reduced.

The present invention has been made in order to solve the above-mentioned problems, and by providing an M code initial value generating section capable of arbitrarily or randomly setting the M code initial value, the spectrum of the transmitted wave can be obtained. The purpose is to obtain an M code generation circuit in which the transmitted wave is spread over a wider band and the confidentiality is improved.

[0010]

The M code generation circuit of the first embodiment according to the present invention can output an initial value corresponding to the M code code length arbitrarily every time the M code change signal is input. By having the value generator, the phase modulation pattern of the transmitted wave can be changed, and thus the spectrum of the transmitted wave can be freely changed.

In the M code generating circuit of the second embodiment according to the present invention, every time the pulse width changing signal is inputted, the M code initial value which can arbitrarily output the initial value corresponding to the M code code length according to the pulse width. By having the generator, the phase modulation pattern of the transmitted wave can be changed, and the spectrum of the transmitted wave can be freely changed. Further, by taking in the pulse width data, it is possible to eliminate the code string in which the code in the modulation signal gate of the transmission wave is "0" or "1".

In the M code generating circuit according to the third embodiment of the present invention, every time the M code changing signal is input, a signal is output from the random signal generating circuit to the M code initial value storage ROM and stored in the ROM. By randomly outputting the initial value, the phase modulation pattern of the transmitted wave can be changed, and thus the spectrum of the transmitted wave can be changed randomly.

In the M code generating circuit of the fourth embodiment according to the present invention, every time the M code changing signal and the pulse width changing signal are inputted, a signal is outputted from the random signal generating circuit to the M code initial value storing ROM, and the ROM By randomly outputting the initial value stored in, it is possible to change the phase modulation pattern of the transmitted wave, and thus to randomly change the spectrum of the transmitted wave. Also, by capturing the pulse width data and selecting the M code length according to the pulse width, the code in the modulation signal gate of the transmission wave is "0".
Alternatively, it is possible to eliminate a code string that is a "1". However, in this case, it is necessary to select an appropriate M code length according to the pulse width, and the selection is performed in the signal processor.

[0014]

The M code generating circuit according to the first embodiment of the present invention has the M code initial value generating section capable of arbitrarily outputting the initial value corresponding to the M code code length each time the M code changing signal is inputted. The phase modulation pattern of the transmitted wave can be changed, the spectrum of the transmitted wave can be changed freely, and the confidentiality can be improved.

The M code generating circuit according to the second embodiment of the present invention generates the M code initial value which can arbitrarily output the initial value corresponding to the M code code length according to the pulse width every time the pulse width changing signal is inputted. By having the section, it becomes possible to change the phase modulation pattern of the transmission wave, and it is possible to eliminate the code string in which the code in the gate of the modulation signal is "0" or "1". Therefore, the spectrum of the transmitted wave changes freely, the transmitted wave is spread over a wider band, and the confidentiality is improved.

In the M code generating circuit according to the third embodiment of the present invention, a random signal for randomly selecting an initial value corresponding to the M code code length from the random signal generating circuit is M every time the M code changing signal is input. Code initial value memory RO
Output to M. Since the M code initial value storage ROM outputs the M code initial value selected by the signal, it becomes possible to change the phase modulation pattern of the transmitted wave, the spectrum of the transmitted wave is changed freely, and the confidentiality is improved. Connect

The M code generation circuit of the fourth embodiment of the present invention randomly selects the pulse width data and the initial value corresponding to the M code code length from the random signal generation circuit every time the pulse width change signal is input. Random signal is M
Output to the code initial value storage ROM. Since the M code initial value storage ROM outputs the M code initial value selected by the signal, it becomes possible to change the phase modulation pattern of the transmission wave, and the code in the gate of the modulation signal is "0" or " Since it is possible to eliminate the code string of "1" (however, in this case, it is necessary to select an appropriate M code length according to the pulse width, and the selection is performed in the signal processor). The spectrum of the transmitted wave changes, the transmitted wave spreads over a wider band, and it becomes possible to increase the confidentiality.

[0018]

【Example】

Example 1. 1 is a block diagram showing a configuration of an M code generation circuit according to a first embodiment of the present invention. In the figure,
8 is the same as the conventional example shown in FIG. An M code initial value generation unit 9 arbitrarily outputs an initial value of the M code corresponding to the M code code length for each M code change signal.

Next, the operation will be described. The operations 1 to 8 in FIG. 1 are the same as in the conventional example. Upon receiving the M code change signal, the M code initial value generation unit 9 arbitrarily sends the M code initial value to the M code generation unit 7 based on the M code code length data.

Now, the pulse width is 400 nsec, the M code code length is 15, and the gate of the modulation signal is 1 bit 80 nse.
If the duty of the output gate of the transmission timing generator is 33%, the initial value (0, 0, 1, 1)
Then, according to FIG. 6, the code string in the gate of the modulation signal is "1.
1000 ". When the M code code length is changed from 15 to 7 by the M code change signal, the code string in the gate of the modulation signal is" 110 "if the M code initial value is constant.
From 00 ”to“ 11001 ”, the first 4 bits are the same code string as before the change, but if the initial value is changed to (0, 0, 1, 0) by the M code change signal, the modulation signal The code string in the gate of is "01011",
Compared to the case where the initial value is constant, the phase modulation pattern of the transmitted wave changes, and therefore the shape of the spectrum of the transmitted wave changes, which makes it possible to increase the confidentiality.

Example 2. FIG. 2 is a block diagram showing the configuration of the M code generation circuit according to the second embodiment of the present invention. In the figure, 1 to 8 are the same as the conventional example shown in FIG. 1
0 is based on the pulse width data for each pulse width change signal,
It is an M code initial value generation unit that arbitrarily outputs an M code initial value corresponding to the M code code length.

Next, the operation will be described. The operations 1 to 8 in FIG. 2 are the same as in the conventional example. Upon receiving the pulse width change signal, the M code initial value generation unit 10 arbitrarily sends the M code initial value corresponding to the M code code length to the M code generation unit 7 based on the pulse width data.

Now, the pulse width is 720 nsec, the M code code length is 15, and the gate of the modulation signal is 1 bit 80 nse.
c, when the duty of the output gate of the transmission timing generator is 33%, according to FIG. 6, the initial value (0, 0, 0,
In 1), the code string in the gate of the modulated signal is “10001.
0011 ”. When the pulse width is changed from 720 nsec to 320 nsec by the pulse width change signal,
If the M code initial value does not change, the code string in the gate of the modulation signal is "1000", but since the initial value is changed according to the pulse width, the ratio of "0" and "1" is evenly modulated. When the signal enters the gate of the signal, the shape of the spectrum of the transmitted wave changes and the confidentiality can be improved.

Example 3. Third Embodiment FIG. 3 is a block diagram showing the configuration of an M code generation circuit according to a third embodiment of the present invention. In the figure, 1 to 8 are the same as the conventional example shown in FIG. 1
Reference numeral 1 is a first random signal generation circuit that randomly generates a signal for each M code change signal, and 12 is an M code that outputs an M code initial value stored at an address selected by the signal of the random signal generation circuit 11. Initial value memory RO
It is M.

Next, the operation will be described. The operations 1 to 8 in FIG. 3 are the same as in the conventional example. Upon receiving the M code change signal, the random signal generating circuit 11 randomly generates a signal for selecting an M code initial value based on the M code code length data. M code initial value storage ROM 12
Sends the initial value of the M code at the address selected by the random signal to the M code generator 7.

When the M code initial value is randomly changed by the M code change signal, the phase modulation pattern of the transmitted wave changes even with the same M code code length and pulse width, and therefore the shape of the spectrum of the transmitted wave changes. It is possible to increase confidentiality.

Example 4. Fourth Embodiment FIG. 4 is a block diagram showing the configuration of an M code generation circuit according to a fourth embodiment of the present invention. In the figure, 1 to 8 are the same as the conventional example shown in FIG. 1
Reference numeral 2 is an M code initial value storage ROM similar to that of the third embodiment shown in FIG. A second random signal generation circuit 13 randomly generates a signal for each pulse width changing signal.

Next, the operation will be described. The operations 1 to 8 in FIG. 4 are the same as in the conventional example. The operation when the random signal generation circuit 13 receives the M code change signal is the same as in the third embodiment. When receiving the pulse width change signal, a signal for selecting the M code initial value is randomly generated based on the pulse width data and the M code code length data. The M code initial value storage ROM 12 sends the M code initial value at the address selected by the random signal to the M code generating unit 7.

When data having a short pulse width is set for an M code having a long code length, the code in the gate of the modulation signal is a code depending on "0" or "1" depending on the timing of changing the pulse width. Although there are cases where there are columns, a code depending on "0" or "1" because the M-code initial value appropriate for the selected pulse width changes randomly with the pulse width change signal due to the processing in the signal processor. It is possible to change the modulation pattern of the transmission wave of the same code length without forming a line, and therefore the shape of the spectrum of the transmission wave also changes,
It is possible to increase confidentiality.

[0030]

The M code generating circuit of the first embodiment of the present invention has an M code initial value generating section capable of arbitrarily outputting an initial value corresponding to the M code code length each time an M code changing signal is input. As a result, the phase modulation pattern of the transmitted wave can be changed, the spectrum of the transmitted wave can be changed freely, and the confidentiality can be improved.

The M code generating circuit of the second embodiment of the present invention generates the M code initial value which can arbitrarily output the initial value corresponding to the M code code length according to the pulse width every time the pulse width changing signal is inputted. By having the section, it becomes possible to change the phase modulation pattern of the transmission wave, and it is possible to eliminate the code string in which the code in the gate of the modulation signal is "0" or "1". Therefore, the spectrum of the transmitted wave changes freely, the transmitted wave is spread over a wider band, and the confidentiality is improved.

In the M code generating circuit according to the third embodiment of the present invention, a random signal for randomly selecting an initial value corresponding to the M code code length from the random signal generating circuit is M each time the M code changing signal is input. Code initial value memory RO
Output to M. Since the M-code initial value storage ROM outputs the M-code initial value selected by the signal, it becomes possible to change the phase modulation pattern of the transmitted wave, the spectrum of the transmitted wave is freely changed, and the confidentiality is improved. Connect

The M code generation circuit of the fourth embodiment of the present invention randomly selects the pulse width data and the initial value corresponding to the M code code length from the random signal generation circuit every time the pulse width change signal is input. Random signal is M
Output to the code initial value storage ROM. Since the M code initial value storage ROM outputs the M code initial value selected by the signal, it becomes possible to change the phase modulation pattern of the transmission wave, and the code in the gate of the modulation signal is "0" or " Since it is possible to eliminate the code string of "1" (however, in this case, it is necessary to select an appropriate M code length according to the pulse width, and the selection is performed in the signal processor). The spectrum of the transmitted wave changes, the transmitted wave spreads over a wider band, and it becomes possible to increase the confidentiality.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an M code generation circuit according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of an M code generation circuit according to a second embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration of an M code generation circuit according to a third embodiment of the present invention.

FIG. 4 is a block diagram showing a configuration of an M code generation circuit according to a fourth embodiment of the present invention.

FIG. 5 is a block diagram showing a configuration of a conventional M code generation circuit of the present invention.

FIG. 6 is a block diagram showing a configuration of an M code generation circuit having a code length of 15;

FIG. 7 is a diagram showing a transmission wave pattern by a conventional M code generation circuit.

[Explanation of symbols]

 1 Bus Transceiver 2 Pulse Width Latch 3 Register 4 Counter 5 Transmission Timing Generator 6 M Code Coefficient Latch 7 M Code Generator 8 AND Gate 9 M Code Initial Value Generator 10 M Code Initial Value Generator 11 First Random Signal Generation circuit 12 M code initial value storage ROM 13 Second random signal generation circuit

Claims (4)

[Claims] 1. A bus for reading data from a signal processor
Transceiver, a pulse width latch that latches and outputs the pulse width data from the bus transceiver, a register that latches and outputs the data from the pulse width latch by the pulse width change signal, and the data from the register as the initial value A counter that counts and outputs a part of the count value to the transmission timing generator, a transmission timing generator that outputs a transmission pulse gate by a signal from the counter, and the longest linear code sequence data from the bus transceiver is latched and output. The longest linear code sequence coefficient latch, the longest linear code sequence generator that outputs a code string according to the data from the longest linear code sequence coefficient latch, and the longest linear code sequence initial value, and the transmission pulse that is output from the transmission timing generator. AND of the code string output from the gate and the longest linear code sequence generator AND to output a modulation signal to take
It is composed of a gate and a longest linear code sequence initial value generation unit that latches the longest linear code sequence change signal by the longest linear code sequence data from the longest linear code sequence number latch and arbitrarily outputs the longest linear code sequence initial value. A longest linear code sequence generation circuit characterized by the above. 2. A bus for reading data from a signal processor.
Transceiver, a pulse width latch that latches and outputs the pulse width data from the bus transceiver, a register that latches and outputs the data from the pulse width latch by the pulse width change signal, and the data from the register as the initial value A counter that counts and outputs a part of the count value to the transmission timing generation unit, a transmission timing generation unit that outputs a transmission pulse gate by the signal from the counter, and the longest linear code sequence data from the bus transceiver is latched and output. The longest linear code sequence coefficient latch, the longest linear code sequence generator that outputs a code string by the data from the longest linear code sequence coefficient latch, and the longest linear code sequence initial value, and the transmission pulse that is output from the transmission timing generator. AND of the code string output from the gate and the longest linear code sequence generator AND to output a modulation signal to take
A longest linear code characterized by comprising a gate and a longest linear code sequence initial value generating section for arbitrarily outputting a longest linear code sequence initial value corresponding to the longest linear code sequence by pulse width data from the pulse width latch. Sequence generator circuit. 3. A bus for reading data from a signal processor.
Transceiver, a pulse width latch that latches and outputs the pulse width data from the bus transceiver, a register that latches and outputs the data from the pulse width latch by the pulse width change signal, and the data from the register as the initial value A counter that counts and outputs a part of the count value to the transmission timing generation unit, a transmission timing generation unit that outputs a transmission pulse gate by the signal from the counter, and the longest linear code sequence data from the bus transceiver is latched and output. The longest linear code sequence coefficient latch, the longest linear code sequence generator that outputs a code string based on the data from the longest linear code sequence coefficient latch, and the longest linear code sequence initial value, and the transmission pulse that is output from the transmission timing generator. AND of the code string output from the gate and the longest linear code sequence generator AND to output a modulation signal to take
It is stored at a gate, a random signal generation circuit that receives the longest linear code sequence data and the longest linear code sequence modification signal and generates a random signal, and an address selected by the random signal output from the random signal generation circuit. A longest linear code sequence generation circuit, comprising: a longest linear code sequence initial value storage ROM for outputting a longest linear code sequence initial value. 4. A bus for reading data from a signal processor.
Transceiver, a pulse width latch that latches and outputs the pulse width data from the bus transceiver, a register that latches and outputs the data from the pulse width latch by the pulse width change signal, and the data from the register as the initial value A counter that counts and outputs a part of the count value to the transmission timing generation unit, a transmission timing generation unit that outputs a transmission pulse gate by the signal from the counter, and the longest linear code sequence data from the bus transceiver is latched and output. The longest linear code sequence coefficient latch, the longest linear code sequence generator that outputs a code string based on the data from the longest linear code sequence coefficient latch, and the longest linear code sequence initial value, and the transmission pulse that is output from the transmission timing generator. AND of the code string output from the gate and the longest linear code sequence generator AND to output a modulation signal to take
A gate, a pulse width data, a longest linear code sequence data, and a random signal generation circuit for generating a random signal in response to a pulse width change signal, and a random signal output from the random signal generation circuit, stored at an address selected by the random signal. And a longest linear code sequence initial value storage ROM for outputting the longest linear code sequence initial value.