JPH0723467A - Spread spectrum communication system - Google Patents

Abstract

PURPOSE:To obtain the network system in which stable communication is attained without causing collision among plural base stations by allowing all base stations and terminal stations to use the same hopping pattern. CONSTITUTION:Suppose that the slot number of hopped frequencies is N slots, an area desired to form a network is divided into N-sets of areas or below. When the number of cells being one unit of the divided area is N, and each of the cells 1-N is allocated with one of base stations B1-BN and plural terminal stations T1-T1M and T21-T2L connecting to the base stations B1-BN, for example, the terminal stations T1-T1M are arranged in the base station B1 and the base stations B1-BN and the terminal stations T1-T1M and T21-T2L are connected by using the low speed frequency hopping spread spectrum communication system. In this case, all the base stations B1-BN are in-wire connection by using a cable 1 and synchronization is taken so that the frequency hopping timing is the same for all the base stations B1-BN.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to improvement of spread spectrum communication system by frequency hopping.

[0002]

2. Description of the Related Art A spread spectrum communication system is a communication system that spreads and transmits a signal in a wider band than the bandwidth of an information signal and is excellent in anti-jamming and confidentiality.
Various applications have been considered by making the most of characteristics such as fading resistance. A communication method using frequency hopping in the spread spectrum communication method will be described below.

FIGS. 6A and 6B are block diagrams of an example of a conventional transmitter and receiver in frequency hopping spread spectrum communication, respectively.

In FIG. 6A, the transmission data 13 is
The modulated signal 1 in the IF frequency band by the modulator 14
It becomes 5. The modulated signal 15 is converted to an RF frequency by the frequency converter 16. At this time, the local oscillation frequency 17 supplied from the frequency synthesizer 31 to the frequency converter 16 is switched according to a predetermined hopping pattern generated by the hopping pattern generator 30. As a result, the spread spectrum signal 18 is generated and passed through the band pass filter (BPF) 19, so that the spread spectrum transmission signal 20 is generated and transmitted from the antenna 32.

In FIG. 6B, the spread spectrum reception signal 21 received by the antenna 33 passes through a bandpass filter (BPF) 22 and is then converted from an RF frequency to an IF frequency by a frequency converter 24. At that time, the local oscillation frequency 25 from the frequency synthesizer 35 supplied to the frequency converter 24 has the same hopping pattern as that on the transmitting side generated by the hopping pattern generator 34, and is synchronized with the hopping timing of the spread spectrum reception signal 21. To switch. As a result, the wideband spread spectrum signal 23 is converted into the narrowband original modulated signal 26 having a constant IF frequency, and the data is demodulated by the demodulator 27. At this time, a part of the modulated signal 26 is supplied to the initial synchronization acquisition and tracking circuit 36 to perform the initial synchronization acquisition and the subsequent synchronization tracking. The spread spectrum signal 23 can also be used for initial synchronization and tracking.

Regarding frequency hopping, "Spread spectrum communication system" by Mitsuo Yokoyama, published by Science and Technology Publishing Company.
It is described in detail in p563 to p611.

When a network is composed of a plurality of base stations and one or more terminal stations, the frequency hopping pattern of the signal transmitted by each base station is an individual pattern, and the hopping timing is also different. Communicate at the timing. Terminal stations connected to one base station use the same hopping pattern.

[0008]

The spectrum distribution in the frequency hopping spread spectrum system is spread over a wide band in a long time observation, but when observed in a short time (for example, in 1-bit units), only a specific frequency band is spread. It is a narrow-band signal for private use. Therefore, depending on the hopping pattern and the hopping timing, a plurality of base stations use the same frequency band, which causes collision.
For example, 100 data transmitted in one frequency band
Even if transmission is carried out using a number of frequency bands, if one frequency band collides with a frequency band used by another base station, the error rate becomes 10 ^-2 .

An object of the present invention is to provide a network system capable of stable communication without causing collision between a plurality of base stations in communication using frequency hopping spread spectrum.

[0010]

In the spread spectrum communication system of the present invention, each base station and the terminal stations belonging to it are connected by low-frequency hopping spread spectrum communication, and a plurality of base stations are wired. connection,
Hopping timings of frequencies are synchronized among all base stations in the network, and hopping patterns are delayed by a predetermined hopping timing so that frequencies used by a plurality of base stations do not overlap at the same timing.

[0011]

With the above-mentioned structure, the present invention uses the same hopping pattern for all base stations and terminal stations, and enables communication without frequency collision between a plurality of base stations.

[0012]

1 is a block diagram of an embodiment of a network system according to the present invention. When the number of frequency hopping slots is N slots, the area in which the network is to be formed is divided into N or less areas. Hereinafter, one unit of the divided area is called a cell. When the number of cells is N, each of the cells 1 to N has one base station B _{1 to} B _N and a plurality of terminal stations connected to the base station.
For example, the base station B ₁ is provided with terminal stations T _{1 to} T _1M , and the base station and the terminal stations are connected using a low-frequency hopping spread spectrum communication system. All base stations are connected by a cable with a cable 1, and synchronization is performed so that frequency hopping timing is the same in all base stations. Also, the frequency hopping pattern is given to all base stations and terminal stations in the same pattern, and a pattern is provided for each predetermined hopping timing so that slots used by a plurality of base stations do not overlap at the same timing. Delay.

The process of synchronizing the hopping timing between the base stations at this time will be described below. An arbitrarily determined one of the plurality of base stations is used as a synchronization control station, and the synchronization signal of hopping timing is transmitted from the control station to each base station. In each base station, frequency hopping is performed in accordance with the hopping timing synchronization signal from the control station, so that the hopping timing is synchronized between the base stations.

Further, each base station and the terminal stations belonging to it are
They are connected by a frequency hopping spread spectrum communication method.First, the base station performs frequency hopping according to the hopping timing synchronized between the base stations, and the information indicating the connectable state with the terminal station and the hopping timing. Transmission of information and waiting for reception of information indicating a connection request from the terminal station are alternately performed. The terminal station waits in the receiving state until the base station uses the slot of the frequency in the slot of the predetermined frequency, and obtains the information indicating the connectable state from the base station and the information of the hopping timing. The initial synchronization is acquired, and then the synchronization follow-up circuit maintains the synchronization to perform communication.

In the above system, the delay time Δt seconds (s) is generated in the synchronization signal of the hopping timing between the base stations depending on the distance of the transmission path from the control station to the base station.
Further, hopping of the frequencies of the base station and the terminal station is performed by switching the frequency with a frequency synthesizer. Normally, the frequency synthesizer has a time t _A (s) from the switching of the frequency to the stabilization, and the transmitting side has , T
_The number of bits of dummy data corresponding to the time of _A (s) or more is set in advance and transmitted, and after the frequency is stabilized, various information data is transmitted. On the receiving side, the number of bits of dummy data is ignored and only various types of information data are recognized as demodulation data.

Here, comparing the maximum delay time Δt _max (s) of the synchronization signal from the control station to the base station with the time t _A (s) until the frequency of the synthesizer stabilizes, Δt
_max << T _A, and the time t _A to the frequency of the synthesizer is stabilized (s) is to become dominant over the number of bits of the dummy data, the synchronization signal hopping timing propagation delay Delta] t (s) is Even if it occurs, it can be considered that the hopping timing synchronization is sufficiently established.

FIG. 2 is a hopping timing chart at each base station. The slot allocation according to the hopping pattern in each base station with respect to the hopping timing T _H when the synchronization of the hopping timing is established between the base stations and the base station B ₁ is the control station is shown. The horizontal axis represents time t. Where h ₁ to h _N are slot numbers, and 1
Corresponding numbers 1 to N on a one-to-one basis. As can be seen from this figure, if the number of base stations is N or less and the synchronization between the base stations is established, duplication of slots at the same timing is eliminated.

As described above, by using the network system using frequency hopping spread spectrum according to the present invention, stable communication can be performed without causing frequency collision between adjacent base stations, which has been inevitable in the past. it can.

Next, the format of data transmitted from each base station will be described. FIG. 3 is an explanatory diagram of an example of the format. In the communication between the base station and the terminal station, the transmission data within one hopping timing is, for example, B bits, and a frame for each B bit is formed. One frame consists of dummy data 2, preamble 3,
It is composed of base station information 4 and information data 5. As a result, at the time of initial synchronization acquisition, even if the information indicating the connectable state from the adjacent cell is received by the terminal station waiting in the reception state in the predetermined slot, the information transmitted by any base station Since it is possible to identify whether there is any, it is possible to avoid accidentally connecting to an adjacent cell.

FIG. 4 is an explanatory diagram of another example of the data format. All the base stations and all the terminal stations have their own clocks, and in the communication between the base station and the terminal stations, the transmission data within one hopping timing is, for example, B bits, and a frame for each B bit is formed. To do. One frame consists of dummy data 6, preamble 7,
It is composed of time information 8 and information data 9. As a result, the terminal station can obtain the relationship between the slot used by the first connection and the time. Therefore, when the connection is lost and then reconnected, the terminal station can easily predict which slot the base station will use next, and change the slot in which the terminal station waits in the receiving state according to the prediction. By doing so, initial synchronization acquisition at the terminal station can be performed at high speed.

It is also possible to combine the format of FIG. 3 with the format of FIG. As described above, since the cable length between the control station and the base station causes a propagation delay time in the synchronization signal of the hopping timing, the hopping timing is accurately deviated. This shift can be corrected as follows. At system startup,
A test signal is transmitted from the control station to each base station, and each base station immediately receives the test signal and immediately transmits a response signal to the control station. The control station can obtain the amount of propagation delay time from the control station to each base station by measuring the time from transmitting the test signal to receiving the response signal for each base station. . By obtaining the amount of propagation delay time in this way, the deviation of the hopping timing in each base station can be corrected, and accurate hopping timing synchronization can be performed in all base stations. Further, even if the length of the cable changes due to the movement of the base station or the like, the deviation of the hopping timing due to the propagation delay time can be easily corrected.

FIG. 5 is a block diagram of an embodiment for performing simultaneous communication with a plurality of terminal stations in the same cell. As shown in the figure, a transmitter and a receiver for frequency hopping spread spectrum communication are paired to form a transceiver block, and a plurality of transceiver blocks C _{1 to} C _N are connected to a control block 40 of a base station. . The control block 40 sends a hopping timing signal 10 to each transceiver block, processes transmission / reception data 11, and sends a control signal 12 for switching between transmission and reception of each transceiver block. For example, the number of frequency slots is N slots, and each base station has the same transceiver block C _{1 as the} number of slots.
~ C _N are incorporated. At this time, the first transceiver block 1 of each base station is used to operate similarly to the system of the above-described embodiment. Transceiver block C
The hopping timing of ₁ is synchronized with the timing of the frequency hopping pattern specific to the base station.

In the transmitter / receiver block C ₂ to the transmitter / receiver block C _N , the same hopping pattern is delayed by one hopping timing and put in the receiving state. By doing so, the communication state of the other cell can be monitored by receiving the communication in the other cell from the transceiver block C _{2 in the} transceiver block C _N.
Further, from the transceiver block C ₂ to the transceiver block C
If there is a transceiver block that is not used among _N , the transceiver block can be used to communicate with the terminal station at the frequency of another slot. By doing so, it is possible to perform simultaneous communication with a plurality of terminal stations in the same cell and other cells, which is not possible in the system of the above-described embodiment.

[0024]

According to the network system using low-speed frequency hopping spread spectrum communication of the present invention, the same hopping pattern can be used in all base stations and terminal stations in the network. Moreover, it is possible to realize a network system capable of stable communication without causing frequency collision between a plurality of base stations.

[Brief description of drawings]

FIG. 1 is a block diagram of an embodiment of the present invention.

FIG. 2 is a hopping timing chart at each base station.

FIG. 3 is an explanatory diagram of an example of a data format.

FIG. 4 is an explanatory diagram of another example of a data format.

FIG. 5 is a block diagram of an example of a base station.

6 (a) and 6 (b) are block diagrams of a conventional frequency hopping spread spectrum communication system transmitter and receiver, respectively.

[Explanation of symbols]

 1 Cable 2,6 Dummy data 3,7 Preamble 4 Base station information 5,9 Information data 8 Time information 10 Hopping timing signal 11 Transmission / reception data 12 Transmission / reception switching control signal 13 Transmission data 14 Modulator 16,24 Frequency converter 19,22 Band pass filter 27 Demodulator

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display point 7304-5K H04B 7/26 109 N H04J 13/00 E

Claims (5)

[Claims] 1. A base station comprising a plurality of base stations and one or more terminal stations connected to each base station by low-frequency hopping spread spectrum communication, wherein all the base stations and the terminal stations have the same hopping pattern. , Multiple base stations are connected by wire to synchronize the frequency hopping timing of each base station, so that the frequency used by each base station does not become the same in the slot of the same hopping timing. Spread spectrum communication method characterized in that the hopping pattern is used at each predetermined hopping timing. 2. The spread spectrum communication system according to claim 1, wherein transmission data is framed for each predetermined number of bits, base station information is added to the frame, and frequency hopping is performed for each frame. . 3. The transmission data is framed for each predetermined number of bits, and time information is added in the frame,
The spread spectrum communication system according to claim 1, wherein frequency hopping is performed for each frame. 4. One of a plurality of base stations is used as a control station, a test signal is transmitted from the control station to each base station when the system is activated, and each base station receives the test signal. Immediately after that, a response signal to the test signal is sent to the control station, and the control station measures the time from when the test signal is sent to when the response signal is received. 2. The spread spectrum communication system according to claim 1, wherein the amount of propagation delay time is used to correct the propagation delay time of the hopping timing signal from the control station. 5. Each base station has a plurality of transmitters / receivers for frequency hopping spread spectrum communication, each transmitter / receiver is set with a different delay amount of a hopping pattern, and according to the delay amount. By operating a plurality of receivers, the frequency usage in other cells is monitored, and if there is a delay amount of the hopping pattern that is not used, the delay amount is used to communicate with a plurality of terminal stations. 2. The simultaneous communication is performed, as claimed in claim 1.
The spread spectrum communication system described.