JP3566435B2 - Wireless switching system - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present inventionWireless communication technologyIt is about.
[0002]
[Prior art]
In recent years, wireless communication has rapidly progressed and has been used in various fields. A telephone exchange device (including a key telephone device) is no exception, and a system for wirelessly communicating between a main device having an exchange function and a wireless telephone has been put to practical use.
[0003]
Hereinafter, a conventional wireless telephone exchange will be described as a first conventional example.
(System configuration)
In a conventional wireless switching system, wireless communication between an extension and a main device generally uses a wireless transmission system for a low-power analog cordless telephone. That is, the modulation method is FM modulation, and two control channels and 87 voice communication channels can be used. Only point-to-point communication is possible. In order for the extension wireless terminal to communicate with the main unit, a connection device for the extension wireless terminal is required.
[0004]
When starting communication, first, a voice communication channel to be used is determined using a control channel. Then, after determining the communication channel to be used, the process shifts to that channel, and thereafter, the communication is continued using the channel.
[0005]
Hereinafter, the configuration and basic operation of each unit of the conventional wireless switching system will be described.
(Configuration of main unit)
FIG. 25 is a block diagram showing a configuration of a conventional system and a main device.
[0006]
Main device 9001 is a main part of the present switching system, accommodates a plurality of external lines and a plurality of terminals, and exchanges calls between them. The connection apparatus 9002 performs control of the wireless terminal wirelessly under the control of the main apparatus in order to be able to accommodate a wireless terminal (wireless telephone set described later) that is wirelessly connected one-to-one to the system. This is a device for establishing a transmission path.
[0007]
The wireless telephone 9003 is a terminal for making a call with an external line accommodated in the main device 9001 via the connection device 9002 and for making an internal call. A PSTN line 9005 is an external line from a PSTN (existing public network) 9004 which is one of the external networks accommodated in the main device 9001, and an SLT (single telephone) 9006 is one of the terminals accommodated in the main device 9001. is there.
[0008]
Hereinafter, the internal configuration of main device 9001 will be described. The CPU 9101 is the center of the main device 9001, and controls the entire main device including exchange control. The ROM 9102 stores a control program of the CPU 9101. The RAM 9103 stores various data for control of the CPU 9101 and provides a work area for various calculations.
[0009]
The communication path unit 9104 is responsible for exchanging calls (time-division exchange) under the control of the CPU 9101. The PSTN line i / f 9105 is an interface that performs PSTN line control, such as detection of an incoming call, transmission of a selection signal, and closing of a DC loop for accommodating the PSTN line 9005 under the control of the CPU 9101. The SLTi / f 9106 is an interface that performs power supply, loop detection, selection signal reception, call signal transmission, and the like for accommodating the SLT 9006 under the control of the CPU 9101.
[0010]
The telephone portion 9107 includes a handset, a dial key, a communication circuit, a display, and the like. When the power is turned on, the telephone portion 9107 functions as a dedicated telephone having a display and the like under the control of the CPU 9101. Only do. The tone transmission circuit 9108 transmits various tones such as a PB signal, a dial tone, and a ring tone. The connection device i / f 9109 is an interface that transmits and receives a call signal and a control signal to and from the connection device 9002 to accommodate the connection device 9002 under the control of the CPU 9101.
(Configuration of connection device)
FIG. 26 is a block diagram showing a configuration of a connection device 9002 in a conventional system.
[0011]
The CPU 9201 is the center of the connection device 9002, and controls the entire connection device 9002 including communication channel control and wireless unit control. The ROM 9202 stores a control program of the CPU 9201, and the EEPROM 9203 stores a call code (system ID) of the switching system. The RAM 9204 stores various data for control of the CPU 9201 and provides a work area for various calculations.
[0012]
The main device i / f 9205 transmits and receives a call signal and a control signal to and from the connection device i / f 9109 of the main device 9001 under the control of the CPU 9201.
[0013]
Under the control of the CPU 9201, the PCM-CODEC 9206 converts a PCM-coded speech signal from the main unit i / f 9205 into an analog audio signal, transmits the analog audio signal to an audio processing LSI 9207 described later, and converts the analog audio from the audio processing LSI 9207. The signal is converted into a PCM code and transmitted to the main unit i / f 9205.
[0014]
The audio processing LSI 9207 receives a demodulated signal from a wireless unit 9208 described below under the control of the CPU 9201, performs A / D conversion when the received signal is control data, outputs the signal to the CPU 9201, and outputs the received signal to the CPU 9201. Is a voice signal, performs processing such as decompression, outputs the data to the PCM-CODEC 9206, D / A converts control data transmitted from the CPU 9201, transmits the control data to the wireless unit 9208, and outputs the voice signal from the PCM-CODEC 9206. , And transmits the result to the radio unit 9208.
[0015]
Under the control of the CPU 9201, the radio unit 9208 modulates the control data and the audio signal from the above-described audio processing LSI 9207 so that they can be transmitted wirelessly and transmits them to the wireless telephone 9003. It demodulates the received signal from the wireless telephone, extracts control data and a voice signal, and transmits the control data and voice signal to the voice processing LSI 9207.
(Configuration of wireless phone only)
FIG. 27 is a block diagram showing a configuration of a wireless telephone 9003 in a conventional system.
[0016]
The CPU 9301 is a central part of the wireless telephone 9003 and is a CPU that controls the entire wireless telephone 9003 including control of a radio unit and call control. The ROM 9302 stores a control program of the CPU 9301, and the EEPROM 9303 stores a call code (system ID) of the switching system and a sub-ID of the wireless telephone.
[0017]
The RAM 9304 stores various data for control of the CPU 9301 and provides a work area for various calculations. The call circuit 9305 is a circuit which inputs and outputs a call signal from a transmitter / receiver 9308, a microphone 9309, and a speaker 9310, which will be described later, under the control of the CPU 9301.
[0018]
The audio processing LSI 9306 receives a demodulated signal from the wireless unit 9307 under the control of the CPU 9301, performs A / D conversion when the received signal is control data, outputs the signal to the CPU 9301, and outputs the received signal to the CPU 9301. In the case of a signal, processing such as decompression is performed and output to the communication circuit 9305, and D / A conversion of control data transmitted from the CPU 9301 is transmitted to the wireless unit 9307 to compress the audio signal from the communication circuit 9305. And transmits it to the wireless unit 9307.
[0019]
Under the control of the CPU 9301, the wireless unit 9307 modulates the control data and the audio signal from the audio processing LSI 9306, processes the control signal and the audio signal so that they can be transmitted wirelessly, transmits the modulated signal to the wireless connection device 9002, and transmits the signal to the wireless connection device 9002. It demodulates a signal received more wirelessly, extracts a signal with control data and voice, and transmits it to the voice processing LSI 9306.
[0020]
The handset 9308 inputs and outputs a voice signal for talking, and the microphone 9309 collects and inputs the voice signal. The speaker 9310 loudspeaker-outputs the audio signal, and the display unit 9311 displays the dial number input from the key matrix 9312, the usage status of the outside line, and the like. Further, the key matrix 9312 includes function keys such as a dial key for inputting a dial number and the like, an outside line key, a hold key, and a speaker key.
(Description of operation of conventional system)
Next, a basic operation of the conventional wireless switching system will be described. FIG. 28 is an explanatory diagram showing a conventional operation sequence.
[0021]
First, when there is a call request in the wireless telephone, the wireless telephone 9003 transmits a connection notification signal (9401) to the connection device 9002 on a predetermined wireless control channel. The connection device that has received the connection notification signal (9401) checks the use status of the wireless communication channel, and transmits a connection response signal (9402) to the wireless telephone 9003 when there is an available communication channel.
[0022]
Upon receiving the connection response signal (9402), the radiotelephone 9003 switches the operating frequency from the radio control channel to the radio communication channel, and transmits a channel movement notification signal (9403) to the connection device. Thereafter, transmission and reception of signals are performed on the communication channel.
[0023]
Upon receiving the signal, the connection apparatus 9002 confirms the shift to the communication channel, and transmits a channel movement response signal (9404) to the wireless telephone. Subsequently, the connection device 9002 transmits a line connection notification (9405) to the main device 9001.
[0024]
Upon receiving the channel movement response signal (9405) and confirming the establishment of the wireless channel, the wireless telephone 9003 transmits an outside line transmission signal (9406) to the connection device. The connection device that has received the outside line transmission signal (9406) transmits an outside line transmission (9407) to the main device. Thereafter, the main apparatus performs an outgoing call operation to an outside line, and when the other party answers, the main apparatus shifts to a call (9412).
[0025]
Through the above procedure, the wireless telephone 9003 can make a call via the public line 9005. Also, for incoming calls, a call can be started by acquiring a wireless communication channel in the same procedure.
[0026]
Next, a second conventional example will be described.
[0027]
Recently, PHS, a digital radio telephone system, has appeared, and is a system for performing radio transmission by performing 4-channel time-division multiplexing (TDMA) on 32 kbps data using a π / 4 shift QPSK modulation scheme. (Corresponding to the connection device) is a system capable of communicating with up to four mobile devices (corresponding to the wireless terminal) at the same time.
[0028]
[Problems to be solved by the invention]
However, in the first conventional example, since the narrow band FM of the analog radio is used as the radio modulation method, there are the following problems.
[0029]
That is, in the first conventional example, the wireless terminal and the connection device have a one-to-one correspondence, and a limited number of specific frequencies are required to establish communication between the connection device and the wireless terminal. If it is necessary to establish a radio link by temporarily monopolizing the allocated control channel, and the control channel cannot be used due to interference or the like, another second control channel can be used as an interference avoidance measure However, since the number of channels is originally limited, an acquisition request is issued from many wireless terminals and connected devices to the same second channel, severe competition occurs, and it takes a very long time to start communication. However, or at worst, there is a disadvantage that the system does not function properly.
[0030]
On the other hand, in the second conventional example, the control channel and the communication channel are time-division multiplexed by adopting the digital radio system, but the control channel and the communication channel are allocated to different frequencies, and the control channel itself is used. Although the number increases due to time division multiplexing, as in the first conventional example, competition for control channel acquisition occurs and it takes time to start communication, and a wireless link is established. However, there is a disadvantage that the control is complicated.
[0031]
SUMMARY OF THE INVENTION It is an object of the present invention to provide an effective control channel interference avoiding means that alleviates or prevents contention of control channels, shortens the time required for connecting a wireless link, and provides effective control channel interference avoidance means.
[0032]
[Means for Solving the Problems]
The present invention provides a wireless switching system accommodating a plurality of wireless terminals, wherein at least one control channel different for each wireless terminal is assigned as a first control channel, and each wireless terminal is provided with a plurality of control channels. Allocating means for allocating in advance, determining means for determining that the control channel is unusable, communication control using the first control channel in response to the determination that the first control channel is unusable by the determining means, Switching means for switching between communication control using another allocated control channel.
[0043]
Embodiments and Examples of the Invention
In recent years, spread spectrum communication has attracted particular attention among digital wireless communication systems. Spread-spectrum communication is known as a technique that spreads information to be transmitted over a wide band, has a high interference removal capability, and is excellent in secrecy. 2.4 GHz band frequencies are allocated for spread spectrum communication in various countries around the world, and are spreading worldwide.
[0044]
The spread spectrum communication schemes are roughly classified into frequency hopping (FH scheme) and direct spread (DS scheme). The former is to transmit over a wide band by changing the modulation frequency within a certain time, and the latter is to spread-modulate the information to be transmitted with a pseudo-noise code whose speed is ten to several hundred times faster. To use a wider band.
[0045]
Therefore, in the present embodiment, a case will be described in which digital wireless communication based on the frequency hopping method is used for transmission between an extension wireless terminal and a connection device of a switching system and between wireless terminals.
[0046]
In the present embodiment, assuming the ISM band in Japan, frequency hopping is performed by selecting 20 channels out of 26 waves (channels), and the control channel between the connection device and the wireless terminal is one frame (hopping). It is assumed that one communication channel is multiplexed in one frame in a transmission / reception four communication slots in one cycle, that is, a signal sequence while staying at one frequency.
[0047]
In this embodiment, control channels corresponding to two frequencies are assigned to one wireless terminal. That is, even if one of the two control channels dedicated to the wireless terminal becomes unavailable due to interference or the like, each wireless terminal can perform interference avoidance using the other control channel. .
[0048]
Therefore, the number of wireless terminals that can establish a control channel by one connection device is equal to 1/2 of the number of control channels corresponding to each frequency to be hopped, and is a maximum of 10. This number does not depend on the number 4 of multiplexed traffic slots of the traffic channel between the connection device and the wireless terminal.
[0049]
In other words, if ten wireless terminals are in a range where one wireless communication is possible with one connection device, and if a control channel is established by registering an ID with the connection device or the like, communication of four channels of the connection device is performed. If there is a free channel, any of the ten wireless terminals can simultaneously communicate with the public line using the communication channel of the connection device, up to a maximum of four.
[0050]
Further, in the present embodiment, the number of multiplexed speech slots in the speech channel between the connection device and the wireless terminal is set to 4, but the number of time-division multiplexed is determined by the processing speed of the wireless device, the processing capability of the control unit, and the like. Differently, it goes without saying that the number can be other than 4, and the number of time division multiplexing = 1, that is, the time division multiplexing need not be performed. Also, it goes without saying that the number of control channels allocated to one wireless terminal is not limited to two and may be more.
(System configuration)
FIG. 1 is an explanatory diagram illustrating a configuration of a system assumed in the present embodiment.
[0051]
The system includes an exchange 101 that accommodates a public line 102 and has an exchange function and a wireless connection function, and a plurality of wireless telephones 103-A and 103-A that communicate control data and voice data between the exchange 101. B and data terminal devices 104-A to 104-F for performing control data communication with the exchange and direct data communication between terminals.
[0052]
The definition of the data terminal device in the present embodiment is “a terminal (data terminal) having a function of transmitting an arbitrary amount of data in a burst manner” and a wireless adapter that performs wireless communication between the data terminal and the main device. The data terminal is not limited to the computer 104-A, but may be a printer 104-B, a copying machine 104-C, a video conference terminal 104-D, a facsimile machine 104-E, a LAN bridge 104-F, and others. , Electronic cameras, video cameras, scanners, and various other terminals that perform data processing.
[0053]
A major feature of this system is that these wireless telephones and data terminals can freely communicate with each other and can also access a public network.
[0054]
Hereinafter, the detailed configuration and operation will be described.
(Configuration of main unit)
First, the configuration of a main device that accommodates a public line will be described.
[0055]
FIG. 2 is a block diagram illustrating a configuration of the system and the main device of the present embodiment.
[0056]
The main apparatus 1 is a main part of the present switching system, accommodates a plurality of external lines and a plurality of terminals, and exchanges calls between them. The connection device 2 performs control of the wireless terminal wirelessly under the control of the main device 1 so that a wireless terminal (a wireless telephone and a data terminal to which a wireless adapter is connected) can be accommodated in the system. The transmission path is established.
[0057]
The wireless telephone 3 is a telephone for making a call with an external line accommodated in the main device via the connection device 2 and for making an internal call with each other. The wireless adapter 4 enables wireless data transmission between similarly configured data terminals by connecting to a data terminal 5, such as a computer or a printer, an SLT (single telephone) 10, a facsimile 11, and an ISDN terminal 12. It is.
[0058]
The PSTN (existing public network) 6 is one of the external networks accommodated in the main device 1, and the PSTN line 7 is an external line from the PSTN 6. The ISDN (digital communication network) 8 is one of the external networks accommodated in the main device 1, and the ISDN line 9 is an external line from the ISDN 8. The SLT (single telephone) 10 is one of the terminals accommodated in the main device 1.
[0059]
Hereinafter, the internal configuration of main device 1 will be described. First, the CPU 201 is the center of the main device 1 and controls the entire main device including exchange control. The CPU 201 allocates a control channel and manages an idle control channel in response to a control channel allocation request from a terminal coming from the connection device i / f 210, and temporarily stores the information in the RAM 203.
[0060]
The ROM 202 stores a control program for the CPU 201, and the RAM 203 stores various data for controlling the CPU 201 and provides a work area for various calculations.
[0061]
The communication path unit 204 is responsible for call exchange (time division exchange) under the control of the CPU 201, and the PSTN line i / f 205 is under the control of the CPU 201 for detecting and selecting an incoming call for accommodating the PSTN line. This interface performs PSTN line control such as signal transmission and DC loop connection. The ISDN line i / f 206 is an interface that supports the ISDN layers 1 and 2 for accommodating the ISDN line under the control of the CPU 201 and controls the ISDN line.
[0062]
The telephone unit 207 has a handset, a dial key, a call circuit, a display, and the like, and functions as a dedicated telephone having a display and the like under the control of the CPU 201 when energized, and as an SLT during a power failure. Only calls are made. The wireless telephone unit 208 has a handset, a dial key, a call circuit, a display, and the like, and functions as an extension wireless telephone under the control of the CPU 201 when energized, and as an SLT during a power failure. .
[0063]
The tone transmission circuit 209 transmits various tones such as a PB signal, a dial tone, and a ring tone. The connection device i / f 210 is an interface that transmits and receives a call signal and a control signal to and from the connection device 2 to accommodate the connection device 2 under the control of the CPU 201.
(Configuration of connection device)
FIG. 3 is a block diagram illustrating a configuration of the connection device 2.
[0064]
The CPU 301 is the center of the connection device 2 and controls the entire connection device 2 including the communication channel control and the radio unit control. The ROM 302 stores a control program of the CPU 301, and the EEPROM 303 stores a call code (system ID) of the switching system. The RAM 304 stores various data for controlling the CPU 301 and provides a work area for various calculations.
[0065]
The main device i / f 305 is an interface that transmits / receives a call signal and a control signal to / from the connection device i / f of the main device 1 under the control of the CPU 301. Under the control of CPU 301, PCM / ADPCM conversion section 306 converts the PCM-encoded call signal from main device 1 to an ADPCM code, transmits the ADPCM code to channel codec 307, which will be described later, and converts the ADPCM code from channel codec 307. The converted speech signal is converted into a PCM code and transmitted to the main device 1.
[0066]
Under the control of the CPU 301, the channel codec 307 performs processing such as scrambling on the ADPCM-encoded call signal and control signal, and also performs time division multiplexing on a predetermined frame. Under the control of CPU 301, radio section 308 modulates the framed digital signal from channel codec 307 so that it can be transmitted wirelessly, transmits it to the antenna, and demodulates the signal received wirelessly from the antenna. Then, the digital signal is processed into a framed digital signal.
(Configuration of wireless phone only)
FIG. 4 is a block diagram showing the configuration of the wireless telephone 3.
[0067]
The CPU 401 is the center of the wireless telephone 3, and controls the entire wireless telephone 3, including the control of the radio unit and the call. The ROM 402 stores a control program of the CPU 401.
[0068]
The EEPROM 403 stores a call code (system ID) of the present exchange system and a sub-ID of the wireless telephone. The RAM 404 stores various data for controlling the CPU 401 and sets a work area for various calculations. To provide.
[0069]
The communication circuit 405 inputs and outputs a communication signal from a transmitter / receiver 410, a microphone 411, and a speaker 412, which will be described later, under the control of the CPU 401.
[0070]
The ADPCM codec 406 converts an analog voice signal from the communication circuit 405 into an ADPCM code under the control of the CPU 401, transmits the ADPCM code to a channel codec 407 described later, and converts the ADPCM-coded communication signal from the channel codec 407 into an analog signal. It is converted into a voice signal and transmitted to the communication circuit.
[0071]
The channel codec 407 performs processing such as scrambling on the ADPCM-encoded call signal and control signal under the control of the CPU 401, and also performs time division multiplexing on a predetermined frame.
[0072]
Under the control of the CPU 401, the radio unit 408 modulates the framed digital signal from the channel codec 407 so that it can be transmitted wirelessly, transmits the modulated signal to an antenna described later, and transmits the signal received wirelessly from the antenna. Is demodulated and processed into a digital signal framed.
[0073]
The handset 410 inputs and outputs a voice signal for talking, and the microphone 411 collects and inputs the voice signal. The speaker 412 loudspeaker-outputs the audio signal, and the display unit 413 displays a dial number input from a key matrix, which will be described later, the usage status of an outside line, and the like.
[0074]
The key matrix 414 includes function keys such as a dial key for inputting a dial number and the like, an outside line key, a hold key, and a speaker key.
(Configuration of wireless adapter)
FIG. 5 is a block diagram showing a configuration of a wireless adapter 502 connected to a data terminal 501 that can be accommodated in the system.
[0075]
In the figure, a data terminal 501 is, for example, a personal computer, a workstation, a printer, a facsimile, or another data terminal device connected to the wireless adapter 502 via a communication cable or an internal bus.
[0076]
The wireless unit 503 of the wireless adapter 502 exchanges wireless signals with the wireless unit of the connection device or another wireless adapter.
[0077]
The main control unit 504 includes a CPU serving as a control center, peripheral devices for performing interrupt control and DMA control, an oscillator for a system clock, and the like, and controls each block in the wireless adapter.
[0078]
The memory 505 includes a ROM for storing a program used by the main control unit 504, a RAM used as a buffer area for various processes, and the like.
[0079]
The communication i / f unit 506 is a communication i / f provided as a standard feature of the data terminal device such as the data terminal 501 described above, for example, a communication i / f such as RS232C, Centronics, and LAN, a personal computer, and a workstation. An internal bus, for example, an ISA bus, PCMCIAi / f or the like corresponds to this.
[0080]
The terminal control unit 507 manages various communication controls necessary for data communication between the data terminal 501 and the wireless adapter 502 via the communication i / f 506.
[0081]
The channel codec 508 performs frame processing and wireless control, and the configuration is shown in FIG. The data assembled into a frame by the channel codec 508 is transmitted to the main device or the opposite terminal via the wireless unit.
[0082]
The error correction processing unit 509 is used to reduce bit errors that occur in data due to wireless communication. At the time of transmission, an error correction code is inserted into the communication data. At the time of reception, an error position and an error pattern are calculated by arithmetic processing, and a bit error in the received data is corrected.
[0083]
The timer 510 provides a timing signal used by each block inside the wireless adapter.
[0084]
FIG. 6 is a block diagram showing a configuration of a wireless adapter with a built-in modem which is necessary when data is transmitted to a public line.
[0085]
This wireless adapter 502 is different from the configuration in FIG. 5 in that an error correction processing unit 509 is not provided, but a modem 511 and an ADPCM codec 512 are provided.
[0086]
The modem 511 modulates data into a voice band signal, and the ADPCM codec 512 encodes a signal modulated by the modem 511. As a result, the ADPCM-encoded data is assembled into a frame by the channel codec 508 and transmitted to the main apparatus via the wireless unit 503.
(Configuration of wireless unit)
FIG. 7 is a block diagram showing a wireless unit having a common configuration in the main apparatus, the wireless telephone, and the data terminal of the present system.
[0087]
The transmitting and receiving antennas 601a and 601b are for efficiently transmitting and receiving wireless signals, and the changeover switch 602 is for switching between the antennas 601a and 601b. A band pass filter (hereinafter, referred to as BPF) 603 is for removing signals in unnecessary bands, and a changeover switch 604 is for switching between transmission and reception.
[0088]
The amplifier 605 is a receiving system amplifier, and the amplifier 606 is a transmission system power control amplifier. The converter 607 includes the 1st. It is a down converter for IF, and converter 608 is an up converter.
[0089]
The changeover switch 609 switches between transmission and reception, and the BPF 610 removes an unnecessary band signal from the signal converted by the downconverter 607. Converter 611 has 2nd. This is a down converter for the IF, and the two down converters 607 and 611 constitute a double conversion type reception mode.
[0090]
BPF612 has 2nd. For the IF, the 90-degree phase shifter 613 shifts the output phase of the BPF 612 by 90 degrees. The quadrature detector 614 detects and demodulates the signal received by the BPF 612 and the 90-degree phase shifter 613. Further, the comparator 615 is for shaping the output of the quadrature detector 614 into a waveform.
[0091]
Also, a voltage-controlled oscillator (hereinafter, referred to as VCO) 616, a low-pass filter (hereinafter, referred to as LPF) 617, and a PLL 618 including a programmable counter, a prescaler, a phase comparator, etc. A frequency synthesizer is configured.
[0092]
A VCO 619 for generating a carrier signal, an LPF 620, and a PLL 621 including a programmable counter, a prescaler, a phase comparator, and the like constitute a frequency synthesizer for hopping.
[0093]
Further, a transmission system frequency synthesizer having a frequency modulation function is configured by the transmission system VCO 622 having a modulation function, the LPF 623, and the PLL 624 including a programmable counter, a prescaler, a phase comparator, and the like.
[0094]
The reference clock oscillator 625 supplies a reference clock for the various PLLs 618, 621, and 624, and the baseband filter 626 is a filter for band limiting transmission data (baseband signal).
[0095]
Hereinafter, the operation of the radio unit as described above will be described.
1. When sending
Data (digital data) input from an external circuit such as a processor is band-limited by a baseband filter 626 and then input to a modulation terminal of a transmission VCO 622.
[0096]
The transmission system VCO 622 determines the frequency based on the control voltage output from the circuits of the transmission system PLL 624 and the LPF 623, and generates an intermediate frequency (IF) modulated wave by direct modulation.
[0097]
The modulated wave of the intermediate frequency (IF) generated by the frequency synthesizer of the VCO 622, the LPF 623, and the PLL 624 is input to the up-converter 608, and is added to the carrier signal generated by the frequency synthesizer including the VCO 619, the LPF 620, and the hopping PLL 621. After that, it is input to the transmission system amplifier 606.
[0098]
The signal amplified to a predetermined level by the transmission system amplifier 606 is removed from a signal in an unnecessary band by the BPF 603, and is then emitted from the antenna 601 to space as a radio wave.
2. When receiving
The signal received by the antenna 601 is removed by a BPF 603 from unnecessary bands, and then amplified to a predetermined level by an amplifier 605 of a receiving system.
[0099]
The received signal amplified to a predetermined level has its carrier signal removed by a down-converter 607, and the 1st. Converted to IF frequency.
[0100]
1st. IF signal of unnecessary band is removed by BPF 610 after 2nd. The signal is input to the down converter 611 for IF.
[0101]
The down-converter 611 includes a signal generated by a frequency synthesizer including the VCO 616, the LPF 617, and the receiving system PLL 618 and a signal generated by the 1st. 2nd. By the input signal from the IF. A signal having an IF frequency is generated.
[0102]
2nd. The received signal down-converted to the IF frequency is input to a 90-degree phase shifter 613 and a quadrature detector 614 after an unnecessary band signal is removed by a BPF 612.
[0103]
The quadrature detector 614 performs detection and demodulation using the signal whose phase has been shifted by the 90-degree phase shifter 613 and the original signal.
[0104]
The data (analog data) demodulated by the quadrature detector 614 is shaped as digital data by the comparator 615 and output to an external circuit.
(Wireless frame)
In the present embodiment, as described below, a time division multiplex frame (PCF) between the connection device and the wireless terminal and a time division multiplex frame (PCF) between the wireless terminals are determined by the channel codecs of the connection device and the wireless terminal. The frame is configured as a frame different from the frame (PPF). Specifically, the PCF and the PPF synchronize the frames, but have different formats and different frequencies at the same point in time for the speech channel portion. Further, the control channel section (CNT-T, CNT-R) of the PPF and the control channel section of the PCF are common (identical). The communication channel units (T1, T2,..., R1, R2,...) Of the PCF have the same frequency as the control channel unit, and the communication channel units (T1, T2,. , R2,...) Use different frequencies from the control channel.
[0105]
Then, the communication channel unit of the PPF establishes a communication channel between the wireless terminals without passing through the connection device. Also, in each wireless terminal, each slot (T1, T2,..., R1, R2,...) Of the communication channel is selected, and the communication data is transmitted to the selected slot, and each of the other terminals communicates. Communication is performed by recognizing the slots from which the call data has been transmitted and receiving the call data transmitted to the respective recognized slots.
[0106]
When the number of accommodated connection devices is two or more, the frames of one PCF and another PCF are made different depending on the channel codecs of the connection device and the wireless terminal. Specifically, one PCF and another PCF have different frequencies at the same time.
[0107]
When the number of accommodated wireless terminals exceeds the number of multiplexed time-division multiplexed frames between wireless terminals (3 in this embodiment), the frame of one PPF and another PPF is divided by the channel codec of the wireless terminal. Make it different. Specifically, the frequencies at the same time point in the communication channel section of the PPF are made different.
[0108]
Further, in this embodiment, the frequency hopping method is adopted, and the frequency of the frame of the PCF and the frequency of the frame of the PPF are switched within a predetermined time, specifically, every frame period. For example, the frame period is 5 ms, the hopping pattern is composed of 20 frequencies, and the multi-frame configuration is 5 ms × 20 = 100 ms.
[0109]
FIG. 8 and FIG. 9 show a radio frame configuration used in the present system.
[0110]
In this system, there are “communication frame between main device and wireless dedicated telephone” (hereinafter referred to as PCF), “communication frame between wireless dedicated telephone” (hereinafter referred to as PPF), and “burst data frame” (hereinafter referred to as BDF). Three different frames are used. Hereinafter, the details of the internal data of each frame will be described.
[0111]
FIG. 8A shows a PCF. In the figure, CNT-T is a control channel transmitted from the connection device including the frame synchronization signal and the logical control channel to the wireless terminal, and CNT-R is a control channel transmitted from the wireless terminal including the logical control channel to the connection device. Channel. Also, T1, T2, T3, and T4 are voice channels sent to four different wireless terminals, and R1, R2, R3, and R4 are voice channels sent from four different wireless terminals. Further, TR is a transmission / reception switching time, and CF is a frequency switching time.
[0112]
In FIG. 8A, F1 and F3 indicate frequency channels used for wirelessly transmitting this frame, and indicate that the frequency is changed for each frame.
[0113]
FIG. 8B shows the PPF. In the figure, CNT-T is a control channel transmitted from the connection device including the frame synchronization signal and the logical control channel to the wireless terminal, and CNT-R is transmitted from the wireless terminal including the logical control channel to the connection device. Control channel. T1, T2, and T3 are voice channels transmitted to three different wireless telephones, and R1, R2, and R3 are voice channels transmitted from three different wireless telephones. Further, CF is a frequency switching time, and RV is a reserve (spare).
[0114]
In FIG. 8B, F1, F3, F5, and F7 are frequency channels used for wirelessly transmitting this frame. Unlike the PCF, the F1 is connected to the wireless terminal by the wireless terminal in F1. After receiving the control channel CNT-T, the frequency channel is switched to F5 secured for the communication between the wireless telephones, and the communication between the wireless telephones is performed.
[0115]
Thereafter, the frequency channel is switched to F1 again to receive a control channel from the wireless telephone to the connection device. Then, after switching the frequency channel to F3 and receiving the control channel from the connection device to the wireless terminal, the frequency channel is switched to F7 secured for the communication between the wireless telephones, and then the frequency is switched again to F3 and the wireless communication is performed. The procedure of receiving the control channel from the dedicated telephone to the connection device is repeated until the communication between the wireless dedicated telephones ends.
[0116]
FIG. 8C shows a BDF. In the figure, CNT-T is a control channel transmitted from the connection device including the frame synchronization signal and the logical control channel to the wireless terminal. After CNT-T, it is a control / data channel between data terminals, CF is a frequency switching time, CS1 is a transmitting terminal carrier transmitting time, CS2 is a receiving terminal carrier transmitting time, R is a transient response ramp time, and PR is a transient response ramp time. UW represents a unique word for capturing byte synchronization, RV represents a reserve (reserve), and DATA represents a data slot for storing burst data.
[0117]
In FIG. 8 (3), F1, F3, F5, and F7 are frequency channels used for wirelessly transmitting this frame, and unlike the PCF, the wireless connection from the connection device is performed at F1. After receiving the control channel to the terminal, the frequency channel is switched to F5 secured for burst data communication, and communication between wireless terminals is performed.
[0118]
Thereafter, the procedure of switching the frequency channel to F3, receiving the control channel from the connection device to the wireless terminal, and then switching the frequency channel to F7 secured for burst data communication is repeated until the burst data communication ends.
[0119]
FIG. 9A shows the configuration of the control channel CNT-T from the connection device to the wireless terminal. In the figure, CS is a carrier sense time, R is a ramp time for a transient response, PR0 is a 62-bit preamble for frequency synchronization acquisition specified by the Radio System Development Center (hereinafter referred to as RCR), and SYN is 1 Dummy bit + 31-bit frame synchronization signal defined by RCR, ID is 63-bit calling signal defined by RCR + 1 dummy bit, UW is a unique word for capturing byte synchronization, BF is a basic (Basic) frame number, and MF is MF. The multi-frame number, LCCHT indicates a logical control channel sent from the connection device to the wireless terminal, and CRC indicates CRC information from UW to LCCHT. The numbers in the figure indicate the number of bits in the present embodiment. In the present embodiment, it is assumed that the LCCHT is assigned as a logical control channel to different wireless terminals for each hopping frequency.
[0120]
FIG. 9 (2) shows a configuration of a communication channel. Since the configurations of T1, T2, T3, and T4 and R1, R2, R3, and R4 are common, the communication channels for transmission are hereinafter collectively indicated as Tn, and the communication channels for reception are collectively indicated as Rn.
[0121]
In the configuration of Tn in the figure, RV is reserved (reserved), PR1 is a preamble for bit synchronization acquisition of each slot, UW is a unique word for byte synchronization acquisition, B is 32 kbps B channel information, and CRC is B GT information and GT indicate a guard time.
[0122]
Further, in the configuration of Rn, portions common to the configuration of Tn are the same as the components of Tn. In addition, CS is a carrier sense time, and R is a ramp time for a transient response. The numbers in the figure indicate the number of bits in the present embodiment.
[0123]
FIG. 9C shows the configuration of the control channel CNT-R from the wireless terminal to the connection device. CS is a carrier sense time, R is a transient response ramp time, PR1 is a preamble for bit synchronization acquisition, and UW is a unique word for byte synchronization acquisition. LCCHR is a logical control channel transmitted from the wireless terminal to the connection device, CRC represents CRC information of LCCHR, and GT represents guard time. The numbers in the figure indicate the number of bits in the present embodiment.
[0124]
In this embodiment, it is assumed that the LCCHR is assigned as a control channel to a different wireless terminal for each hopping frequency.
(Channel codec)
The frames are processed by a channel codec. FIG. 10 is a block diagram illustrating a configuration of the channel codec.
[0125]
In the figure, reference numeral 801 denotes a channel codec; 802, a wireless unit; 803, an ADPCM codec incorporated in a terminal device or the like; and 804, a CPU of a terminal device or a wireless adapter.
[0126]
Further, inside the channel codec 801, the wireless control unit 805 controls transmission and reception switching and frequency hopping for the wireless unit. Further, it has a function of performing carrier detection prior to data transmission. The ADPCM codec i / f 806 is an interface for exchanging serial data and a synchronous clock for exchanging a call signal with the ADPCM codec 803.
[0127]
The CPU i / f 807 is an interface for exchanging control information with the CPU 804, and has a built-in register for storing the state and operation mode of each unit in the channel codec. Then, each part of the channel codec is controlled according to a control signal from the CPU 804 and the state of each part in the channel codec.
[0128]
The transmission frame processing unit 808 assembles the signal from the ADPCM codec and the logical control data input from the CPU 804 into the transmission frame shown in FIGS. The reception frame processing unit 809 extracts control information and call data from a frame of a signal from the wireless unit, and passes the control information and call data to the ADPCM codec i / f806 and the CPU i / f807. The synchronization processing unit 810 is composed of a DPLL, reproduces a clock from a received signal, and captures bit synchronization.
[0129]
Hereinafter, the basic operation of the channel codec will be described.
1. Submit
The CPU i / f 807 receives control information to be added to the transmission data frame from the CPU 804. When the channel codec is used in the terminal device and the connection device in the main device, the transmission frame is assembled by the transmission frame processing unit 808 together with the data from the ADPCM codec 806. If the channel codec is used in the data terminal, the transmission frame is assembled by the transmission frame processing unit 808 together with the error correction coded burst data. At the time of frame assembly, data is scrambled. This is necessary to maintain DC balance during wireless transmission. The radio control unit 805 takes the timing when the reception signal ends, makes the radio unit 802 transmit after carrier sense, and passes the transmission frame to the radio unit 802.
2. Receiving
When the data to be transmitted ends, the wireless control unit 805 switches the wireless unit 802 to reception and waits for a reception frame. Then, upon receiving the received frame, after descrambling the data, control information and data are extracted from the received frame. The control information is passed to the CPU 804 via the CPU i / f 807.
[0130]
When the received frame is a PCF or PPF, the received data is passed to the ADPCM codec i / f 806, and is output as a call signal through the ADPCM codec 803 if it is a terminal device, and is sent to a call path if it is a connection device.
[0131]
If the received frame is a BDF, the received data is transferred to a memory in the data terminal.
3. Handling of logical control data
(3-1) During standby
In accordance with the sequence when the power of the wireless terminal is turned on, the wireless terminal stands by at the frequency assigned by the main device and intermittently receives the LCCHT from the connected device that is periodically transmitted. At this time, the LCCHT sent from the connection device includes information such as presence / absence of an incoming call to an outside line and confirmation of a call request to the wireless terminal. The wireless terminal sends the control data extracted by the reception frame processing unit to the CPU 804. Thereafter, the control data to be sent to the connection device instructed by the CPU 804 is sent to the connection device by LCCHR. Thus, the wireless terminal repeats this procedure until an outgoing or incoming call occurs.
(3-2) During communication
The case where the wireless terminal A makes an outgoing call will be described as an example. It is assumed that the wireless terminal A exchanges the LCCH with the connection device on the frequency channel F1 during no communication. The wireless terminal A monitors the LCCHT from the connection device on the frequency channel F1 according to the procedure described in (3-1) until an outside line transmission request occurs. Then, when an outside line transmission request is generated in the wireless terminal A, the outside line transmission request is put in the LCCHR to be sent to the connection device in the procedure of (3-1) and sent to the connection device. On the other hand, whether or not communication is possible is notified from the connection device side by the LCCHT transmitted on the frequency channel F1.
[0132]
If the content of the LCCHT from the connection device after the external line transmission request indicates that the line is full and connection is not possible, the wireless terminal A notifies the user that the terminal is busy.
[0133]
If the content of the LCCHT from the connection device after the external line transmission request indicates that connection is possible, a time slot of a communication channel used for communication within the same LCCHT is designated. For example, if "1" is designated, it indicates that communication is performed using T1 and R1.
[0134]
Then, communication is performed while switching frequency channels according to the frequency hopping pattern specified at the time of LCCH allocation. The exchange of control information with the connection device after the establishment of the communication channel is also performed by LCCHT and LCCHR.
[0135]
In the case of communication between wireless terminals, control information between the wireless terminals is performed in DATA (burst data channel), and after the communication is completed, each wireless terminal uses the LCCHR of the designated frequency channel. The connection device is notified that the communication between wireless terminals has been completed on the frequency channel F1.
(About frequency hopping pattern)
FIG. 11 is an explanatory diagram illustrating the concept of frequency hopping used in the system of the present embodiment.
[0136]
In the system of the present embodiment, 26 frequency channels having a width of 1 MHz are used, utilizing a 26 MHz band approved for use in Japan. In consideration of a case where there are frequencies that cannot be used due to interference noise or the like, 20 frequency channels are selected from the 26 channels, and frequency hopping is performed on the selected frequency channels in a predetermined order.
[0137]
In this system, one frame has a length of 5 ms, and the frequency channel is hopped for each frame. Therefore, the length of one cycle of one hopping pattern is 100 ms.
[0138]
In the figure, different hopping patterns are indicated by different patterns. As described above, by using a pattern in which the same frequency is not used at the same time in each frame, it is possible to prevent a data error or the like from occurring.
[0139]
When accommodating a plurality of connecting devices, the present system is characterized by using different hopping patterns for each connecting device in order to prevent interference between the connecting devices. This method makes it possible to realize a system having a multi-cell configuration, and to obtain a wide service area.
(Detailed operation explanation)
As described above, in this system, a frame is assembled for communication between a connection device and a wireless telephone or a data terminal, or between terminals, and a frequency to be used is changed at regular intervals (specifically, a frame period). Every time).
[0140]
Hereinafter, the specific operation of the present system will be described in several cases.
1. Basic operation procedure
The present system is characterized in that before using a traffic channel, a traffic slot and a hopping pattern to be used are determined using logical control channels (LCCHT and LCCHR) which are time-division multiplexed in a frame. ing. Furthermore, in order for each wireless terminal to perform intermittent reception and enable battery saving, each wireless terminal is designed to transmit and receive control information only on a logical control channel corresponding to a frequency allocated by the main device. .
[0141]
When a plurality of connection devices are used, the frame including the control channel idle / busy information is received for the first time, and is placed under the management of the connection device that has been able to register the ID.
[0142]
Immediately after the power supply of the main unit (system startup), neither the wireless terminal ID of the wireless terminal nor the control channel frequency to be assigned is determined. Therefore, at the time of system startup, the power of each wireless terminal is turned on in the setting mode to register the wireless terminal ID and assign the logical control channel frequency. At this time, two frequencies are assigned as logical control channel frequencies. When the wireless terminal that has already registered the wireless terminal ID in the system once after the system is started up and the power is turned on again after the battery runs out, the wireless terminal is turned on in the normal mode, so that the wireless terminal is turned on. It is assumed that ID registration and assignment of two logical control channel frequencies are performed.
[0143]
In this embodiment, when two logical control channels are allocated, each terminal enters an intermittent reception state at one of the predetermined control channel frequencies, and receives only the one logical control channel addressed to itself. Do. Then, only when data to be transmitted to the main device is generated, the data is transmitted to the main device using the LCCHR of the allocated control channel.
[0144]
When it is desired to start communication using the communication slot of the communication channel, the main apparatus must be notified of the communication control using the logical control channel, and must be assigned a slot and a hopping pattern. After these assignments have been made, it is possible to make calls and transmit data.
[0145]
In the following, a description will be given of an interference avoidance measure when one of the two control channels, which is a predetermined first intermittently received control channel, becomes unavailable due to interference. It is assumed that the wireless terminal is a wireless telephone 3.
2. Interference avoidance operation when the first control channel cannot be used due to interference
FIG. 12 is an explanatory diagram showing an interference avoidance sequence due to a control channel change when a control terminal cannot receive a control channel in a wireless terminal. FIG. FIG.
[0146]
FIG. 14 is a flowchart showing the operation of the main device when avoiding interference, and FIG. 15 is a flowchart showing the operation of the connected device when avoiding interference. FIG. 16 is a flowchart illustrating an operation of the wireless terminal when avoiding interference.
[0147]
Hereinafter, the interference avoidance operation by changing the control channel in the present embodiment in the main device, the connection device, and the wireless terminal will be described with reference to the flowcharts of FIGS.
[0148]
In this embodiment, the main device counts the number i of control command NACKs received by the first control channel from the connection device, retransmits the same control command until i <N1, and when i = N1, the LCCH When a change command is transmitted and an ACK is received from the connection device for the command, it is determined that the change to the second control channel is possible, and thereafter, the control command is transmitted again.
[0149]
Further, when the main device receives a control command transmission failure indicating that the first control channel cannot be used in the connection device, the main device transmits an LCCH change command. The connection device determines whether transmission on the frequency of the control channel is possible by carrier sense, and when carrier detection is performed on the control channel, transmits a control command transmission disable to the main device and controls the radio terminal on the control channel. After transmitting the command signal, a timer is started, and if ACK from the wireless terminal cannot be received within a predetermined time, a control command NACK is transmitted to the main device.
[0150]
The wireless terminal activates a timer, and changes the reception frequency to the second control channel when the control command signal from the connection device cannot be received on the first control channel for a predetermined time or more.
(1) Description of interference avoidance operation by control channel change of main unit
In S1301 of FIG. 14, the CPU 201 of the main device 1 transmits a control command to the connection device 2 via the connection device i / f 210.
[0151]
On the other hand, in step S1302, when the CPU 201 receives from the connection device 2 via the connection device i / f 210 a control command transmission failure due to the inability to use the first control channel, the process proceeds to step S1308.
[0152]
If the control command transmission disable is not received in S1302, the process proceeds to S1303. In step S1303, when the CPU 201 receives the control command ACK from the connection device 2 via the connection device i / f 210, in this case, there is no interference on the first control channel, and the control command can be transmitted and received normally. That is, the process advances to step S1304 to perform the next process.
[0153]
If the control command ACK has not been received in step S1303, the process advances to step S1305. In step S1305, when the CPU 201 receives the control command NACK from the connection device 2 via the connection device i / f 210, in this case, it is determined that the transmission / reception of the control command was not performed normally due to interference or the like in the first control channel. That is, the process proceeds to S1306.
[0154]
If the control command NACK has not been received in S1305, the process returns to S1302. In S1306, the CPU 201 counts the number i of times the control command NACK has been received (specifically, increments the value of i stored in the RAM 203), makes a determination of i = N1 in S1307, and returns to S1301 if i <N1. , Transmit the same control command again (that is, retransmit).
[0155]
If i = N1, it is determined that transmission of the control command on the first control channel (LCCH) is impossible, and the process advances to S1308 to transmit an LCCH change command to the connection device 2. In step S1309, when the CPU 201 receives from the connection device 2 via the connection device i / f 210 a notification indicating that the second control channel cannot be used to transmit the LCCH change command, the process proceeds to step S1314 to perform another interference avoidance process. If it is determined in step S1309 that the transmission failure of the LCCH change command has not been received, the process advances to step S1310.
[0156]
In step S1310, when the CPU 201 receives the LCCH change command ACK from the connection device 2 via the connection device i / f 210, in this case, there is no interference in the second control channel, and the transmission and reception of the LCCH change command can be performed normally. That is, the process proceeds to S1315.
[0157]
If the control command ACK has not been received in S1310, the process proceeds to S1311. In step S1311, when the CPU 201 receives the LCCH change command NACK from the connection device 2 via the connection device i / f 210, in this case, the transmission and reception of the LCCH change command are normally performed also on the second control channel due to interference or the like. That is, the process goes to S1312.
[0158]
If the LCCH change command NACK has not been received in S1311, the process returns to S1309.
[0159]
In S1312, the CPU 201 counts the number i of times of receiving the LCCH change command NACK (specifically, increments the value of i stored in the RAM 203), determines i = N2 in S1313, and if i <N2, S1308 And sends the same LCCH change command again (that is, retransmits).
[0160]
If i = N2, it is determined that transmission of a control command on the second control channel (LCCH) is impossible, and the process advances to S1314 to perform another interference avoidance process.
[0161]
In S1315, the control command is transmitted. Next, in step S1316, when the CPU 201 receives, via the connection device i / f 210, a control command transmission failure from the connection device 2 due to the inability to use the second control channel, the process advances to step S1314 to perform another interference avoidance process. If the control command transmission disable is not received in S1316, the process advances to S1317.
[0162]
In step S1317, when the CPU 201 receives the control command ACK from the connection device 2 via the connection device i / f 210, in this case, there is no interference on the second control channel, and the control command can be normally transmitted and received. That is, the process advances to step S1318 to perform the next process. If the control command ACK has not been received in S1317, the process advances to S1319.
[0163]
In step S1319, when the CPU 201 receives the control command NACK from the connection device 2 via the connection device i / f 210, in this case, the transmission and reception of the control command were not performed normally due to interference or the like in the second control channel. That is, the process proceeds to S1320. If the control command NACK has not been received in S1319, the process returns to S1316.
[0164]
In S1320, the CPU 201 counts the number i of times of receiving the control command NACK (specifically, increments the value of i stored in the RAM 203), determines i = N1 in S1321, and if i <N1, proceeds to S1315. Then, the same control command is transmitted again (that is, retransmitted).
[0165]
If i = N1, it is determined that transmission of the control command on the second control channel (LCCH) is impossible, and the process advances to S1314 to perform another interference avoidance process.
(2) Description of interference avoidance operation due to change of control channel of connected device
In S1401 of FIG. 15, when the CPU 301 of the connection device 2 receives a control command from the main device 1 via the main device i / f 305, the CPU 301 of the wireless device 308 transmits a control command signal on the first control channel in S1402. If it is possible, carrier sense of the control channel frequency is performed. If the carrier is detected and the control command cannot be transmitted, a control command transmission disable is transmitted to the main device 1 in S1403.
[0166]
If no carrier is detected in S1402 and a control command can be transmitted, a control command signal is transmitted to the wireless terminal 3 in S1404. On the other hand, when the control command signal ACK is received from the wireless terminal 3 in S1405, the control command ACK is transmitted to the main device 1 in S1406, and the process returns to S1401 to receive the next control command.
[0167]
If the control command signal ACK cannot be received in S1405, the timer is operated in S1407, and the reception of the control command signal ACK is repeated until a timeout occurs. When the timeout occurs, in S1409, the CPU 301 transmits the main device 1 To transmit a control command NACK.
[0168]
Subsequently, when the CPU 301 receives the LCCH change command from the main device 1 via the main device i / f 305 in S1409, the process proceeds to S1410. If an LCCH change command has not been received in S1409, the process returns to S1401.
[0169]
In S1410, the CPU 301 performs carrier sensing on the control channel frequency in the radio unit 308 to determine whether an LCCH change command signal can be transmitted on the second control channel. If a carrier is detected and the LCCH change command cannot be transmitted, the main unit determines in S1411 1 is transmitted to indicate that the LCCH change command cannot be transmitted.
[0170]
If no carrier is detected in S1410 and an LCCH change command can be transmitted, an LCCH change command signal is transmitted to the wireless terminal 3 in S1412. On the other hand, if an LCCH change command signal ACK is received from the wireless terminal 3 in S1413, the process proceeds to S1419.
[0171]
If the LCCH change command signal ACK cannot be received in S1413, the timer is operated in S1414, and the reception of the LCCH change command signal ACK is repeated until a timeout occurs. An LCCH change command NACK is transmitted to the main device 1.
[0172]
When the CPU 301 receives the LCCH change command again from the main device 1 via the main device i / f 305 in S1416, the process returns to S1410.
[0173]
If no LCCH change command has been received in S1416, the process advances to S1417. If another interference avoidance control command is received, another interference avoidance process is performed in S1418.
[0174]
In step S1419, the CPU 301 transmits an LCCH change command ACK to the main device 1 via the main device i / f 305.
[0175]
Next, when a control command is received from the main device 1 in S1420, in S1421 the CPU 301 performs a carrier sense of the control channel frequency in the wireless unit 308 to determine whether a control command signal can be transmitted on the second control channel. If it is detected that the transmission of the control command is impossible, a transmission of the impossibility of transmission of the control command is transmitted to the main device 1 in S1422.
[0176]
If no carrier is detected in S1421 and a control command can be transmitted, a control command signal is transmitted to the wireless terminal 3 on the second control channel (LCCH) in S1423.
[0177]
On the other hand, when the control command signal ACK is received from the wireless terminal 3 in S1424, the control command ACK is transmitted to the main device 1 in S1425, and the process returns to S1420 to receive the next control command.
[0178]
If the control command signal ACK cannot be received in S1424, the timer is operated in S1407, and the control command signal ACK reception is repeated until a timeout occurs. A control command NACK is transmitted, and the process returns to S1420 to receive a control command from the main device.
(3) Description of interference avoidance operation due to control channel change of wireless terminal
In S1501 of FIG. 16, when the CPU 401 of the wireless terminal 3 receives a control command signal from the connection device 2 via the wireless unit 408, the CPU 401 sends a control command signal ACK to the connection device 2 via the wireless unit 408 in S1502. Send.
[0179]
If the control command signal has not been received in S1501, the timer is operated in S1503, and the control command reception is repeated until a timeout occurs. Change the reception frequency.
[0180]
Then, when an LCCH change command signal is received from the connection device 2 in S1505, an LCCH change command signal ACK is transmitted to the connection device 2 in S1506, and the process proceeds to S1507.
[0181]
If the LCCH change command signal has not been received in S1505, the timer is operated in S1511 and the reception of the LCCH change command signal is repeated until a timeout occurs. When the timeout occurs, the process proceeds to S1510 to perform another interference avoidance process.
[0182]
Next, in step S1507, when the CPU 401 receives a control command signal from the connection device 2 via the wireless unit 408, the CPU 401 transmits a control command signal ACK to the connection device 2 via the wireless unit 408 in step S1508, and returns to step S1507. .
[0183]
If the control command signal has not been received in S1507, the timer is operated in S1509, the control command reception is repeated until a timeout occurs, and when the timeout occurs, another interference avoidance process is performed in S1510.
[0184]
As described above, in the first embodiment of the present invention, means for establishing individual control channels between a predetermined number of wireless terminals and connection devices, means for assigning a plurality of control channels to wireless terminals, Is provided, it is possible to use the control channel individually for each wireless terminal, it is possible to prevent contention of the control channel, and it is possible to shorten the time required for connecting a wireless link. is there.
[0185]
Further, even if one control channel becomes unavailable due to interference, another control channel assigned in advance to replace the unavailable control channel exists. It is possible to mitigate or prevent the occurrence of channel contention, and it is possible to quickly and effectively avoid control channel interference.
[0186]
In addition, by allocating different control channels to each wireless terminal, there is an effect that interference of a control channel can be performed without affecting other wireless terminals when avoiding interference.
[0187]
In addition, by simultaneously using one control channel among a plurality of control channels allocated for the wireless terminal, there is an effect that the number of control channels to be used can be suppressed and interference with other cells can be suppressed. .
[0188]
Further, by making the frequency of the time division multiplex frame between one connection device and the radio terminal and the time division multiplex frame between the other connection device and the radio terminal different at the same time, each frame is This makes it possible to distinguish them and to perform communication at the same time without interference.
[0189]
Further, by switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal within a predetermined time, that is, by performing frequency hopping, which is one method of spread spectrum, the interference removal capability is enhanced, This has the effect of improving confidentiality.
[0190]
Also, by switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal for each frame period, that is, by performing frequency hopping, which is a method of spread spectrum, the interference removal capability is enhanced, and By performing frequency hopping on a frame-by-frame basis, the timing of frame transmission and reception and the timing of frequency hopping are integrated, simplifying circuits and control, and providing advantages in terms of cost. is there.
[0191]
In the first embodiment described above, when a call exchange connection between the public line and the wireless terminal is performed via the connection device, the time switch of the communication path of the main device is connected between the connection device and the public line. The main unit is not provided with a time switch, but only the exchange of the call slot on the time-division multiplexed frame between the connection device and the wireless terminal is performed. It is also possible to make a call exchange connection between and.
[0192]
Further, in the first embodiment, the number of control channels allocated to each wireless terminal is set to two. However, it is needless to say that three or more control channels may be used, and an available control channel is selected from a plurality of allocated control channels. Then, interference may be avoided.
[0193]
Also, the number of control channels to be allocated to the wireless terminals does not necessarily need to be uniform, and many control channels may be allocated to wireless terminals having higher priorities depending on the priority of the wireless terminals.
[0194]
In the first embodiment, the control channel in the time-division multiplex frame between the connection device and the wireless terminal is used for one wireless terminal. However, the control channel is further allocated to the control slots for a plurality of wireless terminals. It may be used in a time-sharing manner.
[0195]
Furthermore, the configuration of the main device, the connection device, the wireless terminal, the wireless configuration, the hardware configuration of the channel codec, the format of the wireless frame (the number of control channels set to 20 in this embodiment, the number of multiplexed speech slots set to 4 in the above embodiment) , Other detailed configurations of the control channel unit and the communication channel unit), a frequency hopping control method (the number of hopping frequencies assumed to be 20 in the present embodiment, etc.), a main device for control channel interference avoidance operation, a connection device, and a wireless terminal It is needless to say that the function allocation and control channel change condition and the specific interference avoidance operation procedure are not limited to the above-described embodiment, and can be changed without departing from the gist of the present invention.
[0196]
Next, a second embodiment of the present invention will be described.
[0197]
In the first embodiment, two logical control channels are assigned to each wireless terminal. In the second embodiment, one logical control channel is assigned to each wireless terminal, and each wireless terminal is assigned. A plurality of spare logical control channels are prepared in common and are changed to the spare logical control channel when the first logical control channel interferes.
[0198]
The hardware configuration and the basic operation procedure of each unit of the present embodiment are the same as those of the first embodiment, and the “second control channel (LCCH)” in FIGS. 12 to 16 is replaced with the “backup control channel (LCCH)”. Only the point is different.
[0199]
As described above, according to the second embodiment, means for establishing a separate control channel between a predetermined number of wireless terminals and a connection device, and means for allocating a plurality of control channels to a wireless terminal are provided. With the provision, it is possible to use the control channel individually for each wireless terminal, it is possible to prevent contention of control channels, and it is possible to shorten the time required for connecting a wireless link.
[0200]
Further, even if one control channel becomes unavailable due to interference, another control channel that is assigned in advance to replace the unavailable control channel exists. It is possible to mitigate or prevent the occurrence of channel contention, and it is possible to quickly and effectively avoid control channel interference.
[0201]
In addition, by simultaneously using one control channel among a plurality of control channels allocated for a wireless terminal, the number of control channels to be used can be reduced, and interference with other cells can be suppressed. is there.
[0202]
Further, by making the frequency of the time division multiplex frame between one connection device and the radio terminal and the time division multiplex frame between the other connection device and the radio terminal different at the same time, each frame is This makes it possible to distinguish them and to perform communication at the same time without interference.
[0203]
Further, by switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal within a predetermined time, that is, by performing frequency hopping, which is one method of spread spectrum, the interference removal capability is enhanced, This has the effect of improving confidentiality.
[0204]
Also, by switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal for each frame period, that is, by performing frequency hopping, which is a method of spread spectrum, the interference removal capability is enhanced, and By performing frequency hopping on a frame-by-frame basis, the timing of frame transmission and reception and the timing of frequency hopping are integrated, simplifying circuits and control, and providing the advantage of cost reduction. is there.
[0205]
Further, by allocating one different control channel to each wireless terminal and allocating a plurality of common spare control channels to a plurality of wireless terminals, the control channel is allocated as compared to a case where a different control channel is allocated to each wireless terminal. It is possible to effectively utilize the wireless terminal and to increase the number of wireless terminals that can be accommodated in one connection device.
[0206]
In the above-described second embodiment, when a call exchange connection between the public line and the wireless terminal is performed via the connection device, the time switch of the communication unit of the main device is connected between the connection device and the public line. The main unit is not provided with a time switch, but only the exchange of the call slot on the time-division multiplexed frame between the connection device and the wireless terminal is performed. It is also possible to make a call exchange connection between and.
[0207]
Further, in the second embodiment, the number of control channels assigned to each wireless terminal in advance is one, but two or more control channels are assigned in advance, and a common spare control channel is prepared. Needless to say, the number of spare control channels to be assigned to one wireless terminal is not limited to one, and a plurality of spare control channels may be assigned, and an available control channel is selected from a plurality of spare control channels. You may do it.
[0208]
Further, the number of control channels including the spare control channels to be allocated to the wireless terminals does not necessarily need to be uniform, and many control channels may be allocated to wireless terminals having higher priorities depending on the priority of the wireless terminals.
[0209]
Further, in the second embodiment, the control channel in the time division multiplex frame between the connection device and the wireless terminal is used for one wireless terminal, but the control channel is used for controlling a plurality of wireless terminals. The slots may be used in a time-sharing manner.
[0210]
Furthermore, the configuration of the main unit, the connection device, the radio terminal, the radio configuration, the hardware configuration of the channel codec, the format of the radio frame (the number of control channels set to 20 in this embodiment, the number of multiplexed speech slots set to 4 in this embodiment) , Other detailed configurations of the control channel unit and the communication channel unit), a frequency hopping control method (the number of hopping frequencies assumed to be 20 in the present embodiment, etc.), a main device for control channel interference avoidance operation, a connection device, and a wireless terminal It is needless to say that the conditions for changing the functions and the change to the spare control channel, and the specific interference avoiding operation procedure are not limited to the present embodiment, and can be changed without departing from the gist of the present invention.
[0211]
Next, a third embodiment of the present invention will be described.
[0212]
In the first and second embodiments, when one logical control channel assigned in advance to each wireless terminal becomes unusable due to interference or the like, it is changed to the second or spare logical control channel. In the third embodiment, as in the first embodiment, the assignment of two logical control channels to each wireless terminal is the same as in the first embodiment. Control information is transmitted / received using one logical control channel, and even when one of the logical control channels becomes unavailable due to interference, control information is continuously transmitted / received on the remaining logical control channels.
[0213]
FIGS. 17 and 18 are explanatory diagrams showing an interference avoidance sequence by using the control channel in parallel according to the present embodiment when the wireless terminal cannot receive the control channel, and FIGS. 19 and 20 show that the connection device cannot transmit the control channel. FIG. 8 is an explanatory diagram showing an interference avoidance sequence by using control channels in parallel according to the embodiment in the case of FIG.
[0214]
21 and 22 are flowcharts showing the operation of the main device when avoiding interference, and FIG. 23 is a flowchart showing the operation of the connecting device when avoiding interference. FIG. 24 is a flowchart illustrating an operation of the wireless terminal when avoiding interference.
[0215]
Hereinafter, the interference avoiding operation by the parallel use of the control channel in the present embodiment in the main device, the connection device, and the wireless terminal will be described with reference to the flowcharts of FIGS.
[0216]
In this embodiment, the main device counts the number i, j of control command NACK receptions by the first and second control channels from the connection device, respectively, and when the control command transmission / reception fails on the other control channel, The same control command is transmitted until i <N1 (or j <N1).
[0217]
Similarly, the number of times k and l in which the control command cannot be transmitted by the first and second control channels are counted, and if the transmission and reception of the control command on the other control channel fails, k <N2 (or 1 <N2) Retransmit the same control command.
[0218]
Then, when the control command transmission / reception succeeds on one of the two control channels, the next control command is transmitted. The connection device determines whether transmission at the frequency of the control channel is possible by carrier sense, and when a carrier is sensed in the control channel, transmits a control command transmission disable to the main device, and transmits to the wireless terminal on the control channel. After transmitting the control command signal thereto, a timer is started, and if ACK from the wireless terminal cannot be received within a predetermined time, a control command NACK is transmitted to the main device.
[0219]
The wireless terminal switches the transmission and reception frequencies for the first and second control channels allocated in synchronization with the wireless multi-frame, respectively, and repeats the switching.
(1) Description of interference avoidance operation by using control channels in parallel in main unit
In S1801 of FIG. 21, the CPU 201 of the main device 1 sets the number I of the control command for the wireless terminal transmitted to the connection device 2 to I = I0. Next, the CPU 201 transmits a control command I to the connection device 2 via the connection device i / f 210.
[0220]
On the other hand, if it is determined in step S1803 that the control command cannot be transmitted by the first LCCH from the connection device 2, the process advances to step S1820. If it is determined in step S1803 that the control command cannot be transmitted using the first LCCH, the process advances to step S1804.
[0221]
Upon receiving the control command ACK using the first LCCH from the connection device 2 in S1804, the process returns to S1802 after setting I = I + 1 in S1805 (that is, transmits the next control command to the connection device 2).
[0222]
If the control command ACK using the first LCCH has not been received in step S1804, the process advances to step S1806. Then, when the control command NACK by the first LCCH is received from the connection device 2 in S1806, the number of NACK receptions i is counted in S1807, and the process proceeds to S1808. If the control command NACK using the first LCCH has not been received in S1806, the process returns to S1804.
[0223]
In step S1808, if the CPU 201 receives from the connection device 2 via the connection device i / f 210 that the control command cannot be transmitted by the second LCCH, the process proceeds to step S1816. If it is determined in step S1808 that the control command cannot be transmitted by the second LCCH, the process proceeds to step S1809.
[0224]
In S1809, upon receiving the control command ACK using the second LCCH from the connection device 2, the process returns to S1802 after setting I = I + 1 in S1810 (that is, transmits the next control command to the connection device 2). If the control command ACK using the second LCCH has not been received in step S1809, the process advances to step S1811.
[0225]
In S1811, when the control command NACK by the second LCCH is received from the connection device 2, the number of NACK receptions j is counted in S1812, and the process proceeds to S1813. If the control command NACK by the second LCCH has not been received in S1811, the process returns to S1809.
[0226]
Also, in S1813, if the number of NACK receptions i of the control command I by the first LCCH i <N1, the process returns to S1802 and retransmits the control command I to the connection device 2.
[0227]
If i ≧ N1 in S1813, the process proceeds to S1814. In S1814, if the number of NACK receptions j of the control command I by the second LCCH j <N1, the process returns to S1802 and retransmits the control command I to the connection device 2. If j ≧ N1 in S1814, the process advances to S1815 to perform another interference avoidance process.
[0228]
On the other hand, in S1816 following S1808, the number of times 1 that transmission of the control command I by the second LCCH is not possible is counted. , Retransmit the control command I to the connection device 2.
[0229]
If i ≧ N1 in step S1817, the process advances to step S1818. If it is determined in S1818 that the number of times that the control command I cannot be transmitted by the second LCCH can be transmitted, l <N2, the process returns to S1802 and retransmits the control command I to the connection device 2. If l ≧ N2 in step S1818, the process advances to step S1819 to perform another interference avoidance process.
[0230]
Also, in S1820 following S1803, the number k of times the control command I cannot be transmitted by the first LCCH is counted, and the process proceeds to S1821. In S1821, if the CPU 201 receives from the connection device 2 via the connection device i / f 210 that the control command cannot be transmitted by the second LCCH, the process proceeds to S1829.
[0231]
If the control command transmission disable by the second LCCH is not received in S1821, the process proceeds to S1822. Then, in S1822, upon receiving the control command ACK by the second LCCH from the connection device 2, after setting I = I + 1 in S1823, the process returns to S1802 (that is, the next control command is transmitted to the connection device 2). .
[0232]
If the control command ACK using the second LCCH has not been received in S1822, the process proceeds to S1824. In S1824, when the control command NACK by the second LCCH is received from the connection device 2, the number of NACK receptions j is counted in S1825, and the process proceeds to S1826. Then, in S1826, when the control command NACK by the second LCCH has not been received, the process returns to S1822.
[0233]
If it is determined in step S1826 that the number of times that the control command I cannot be transmitted by the first LCCH cannot be transmitted (k <N2), the process returns to step S1802 and retransmits the control command I to the connection device 2. Further, if k ≧ N2 in S1826, the process proceeds to S1827.
[0234]
In S1827, if the number of times NACK of the control command I received by the second LCCH is j <N1, the process returns to S1802 and retransmits the control command I to the connection device 2. If j ≧ N1 in S1827, the process advances to S1828 to perform another interference avoidance process.
[0235]
On the other hand, following S1821, in S1829, the number of times 1 that the control command I cannot be transmitted by the second LCCH is unreceivable is counted. Then, the control command I is retransmitted to the connection device 2. If k ≧ N2 in S1830, the process proceeds to S1831.
[0236]
In S1831, if the number of times that the control command I cannot be transmitted by the second LCCH cannot be transmitted, l <N2, the process returns to S1802 and retransmits the control command I to the connection device 2. If l ≧ N2 in S1831, the process advances to S1832 to perform another interference avoidance process.
(2) Description of interference avoidance operation by parallel use of control channels by connecting devices
In S1901 of FIG. 23, when the CPU 301 of the connection device 2 receives the control command from the main device 1 via the main device i / f 305, the CPU 301 in the wireless unit 308 transmits a control command signal on the first LCCH in S1902. If it is possible, carrier sense of the control channel frequency is performed, and if a carrier is detected and the control command cannot be transmitted, a control command transmission impossibility by the first LCCH is transmitted to the main device 1 in S1903, and the process proceeds to S1909.
[0237]
If no carrier is detected in S1902 and a control command can be transmitted, a control command signal is transmitted to the wireless terminal 3 on the first LCCH in S1904. On the other hand, when the control command signal ACK on the first LCCH is received from the wireless terminal 3 in S1905, a control command ACK by the first LCCH is transmitted to the main device 1 in S1906, and the process proceeds to S1909.
[0238]
If the control command signal ACK by the first LCCH has not been received in S1905, the timer is operated in S1907, and the reception of the control command signal ACK is repeated until a timeout occurs. A control command NACK using the first LCCH is transmitted to the main device 1 via the main device 1, and the process proceeds to S1909.
[0239]
In S1909, the CPU 301 performs carrier sensing on the control channel frequency in the radio unit 308 to determine whether a control command signal can be transmitted on the second LCCH. If a carrier is detected and the control command cannot be transmitted, the main unit determines in S1910. 1, the control command transmission impossible by the second LCCH is transmitted, and the process proceeds to S1916.
[0240]
If no carrier is detected in S1909 and a control command can be transmitted, a control command signal is transmitted to the wireless terminal 3 on the second LCCH in S1911. On the other hand, if a control command signal ACK is received from the wireless terminal 3 in the second LCCH in S1912, a control command ACK by the second LCCH is transmitted to the main device 1 in S1913, and the process proceeds to S1916.
[0241]
If the control command signal ACK by the first LCCH cannot be received in S1912, the timer is operated in S1914, and the reception of the control command signal ACK is repeated until a timeout occurs. A control command NACK using the second LCCH is transmitted to the main device 1 via f305, and the process proceeds to S1916.
[0242]
When another interference avoidance control command is received in S1916, another interference avoidance processing is performed in S1917. If another interference avoidance control command has not been received in S1916, the process returns to S1901.
(3) Description of interference avoidance operation of wireless terminal using control channel in parallel
In S2001 of FIG. 24, the CPU 401 of the wireless terminal 3 controls the wireless unit 408 to set a reception frequency for the first control channel (LCCH). In S2002, when the CPU 401 receives a control command signal on the first LCCH from the connection device 2 via the wireless unit 408, in S2003, the CPU 401 sends a control command signal on the first LCCH to the connection device 2 via the wireless unit 408. An ACK is transmitted, and the process proceeds to S2005.
[0243]
If the control command signal is not received in S2002, the timer is operated in S2004, and the control command reception is repeated until timeout occurs. When the timeout occurs, the wireless unit 408 is controlled in S2005 to control the second control channel (LCCH). Set the receiving frequency for).
[0244]
Next, in step S2006, when the CPU 401 receives a control command signal on the second LCCH from the connection device 2 via the wireless unit 408, the CPU 401 controls the connection device 2 via the wireless unit 408 on the second LCCH in step S2007. A command signal ACK is transmitted, and the process returns to S2001.
[0245]
If the control command signal has not been received in S2006, the timer is operated in S2008, and the control command reception is repeated until a timeout occurs. When the timeout occurs, the process returns to S2001 to control the radio unit 408 to control the first control channel ( Set the receiving frequency for (LCCH).
[0246]
As described above, according to the third embodiment, a means for establishing a separate control channel between a predetermined number of wireless terminals and a connection device, and a means for assigning a plurality of control channels to a wireless terminal are provided. With the provision, it is possible to use the control channel individually for each wireless terminal, it is possible to prevent contention of control channels, and it is possible to shorten the time required for connecting a wireless link.
[0247]
Further, even if one control channel becomes unavailable due to interference, another control channel assigned in advance to replace the unavailable control channel exists. It is possible to mitigate or prevent the occurrence of channel contention, and it is possible to quickly and effectively avoid control channel interference.
[0248]
In addition, by allocating different control channels to each wireless terminal, there is an effect that it is possible to avoid interference of a control channel without affecting other wireless terminals when avoiding interference.
[0249]
Further, by making the frequency of the time division multiplex frame between one connection device and the radio terminal and the time division multiplex frame between the other connection device and the radio terminal different at the same time, each frame is This makes it possible to distinguish them and to perform communication at the same time without interference.
[0250]
Further, by switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal within a predetermined time, that is, by performing frequency hopping, which is one method of spread spectrum, the interference removal capability is enhanced, This has the effect of improving the secret family name.
[0251]
Also, by switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal for each frame period, that is, by performing frequency hopping, which is a method of spread spectrum, the interference removal capability is enhanced, and By performing frequency hopping on a frame-by-frame basis, the timing of frame transmission and reception and the timing of frequency hopping are integrated, simplifying circuits and control, and providing the advantage of cost reduction. is there.
[0252]
Furthermore, by using a plurality of control channels allocated for the wireless terminal in parallel, there is no need to perform a process of changing the control channel, and it is possible to quickly avoid interference of the control channel. .
[0253]
In the third embodiment, when a call exchange connection between the public line and the wireless terminal is performed via the connection device, the time switch of the communication path of the main device is connected between the connection device and the public line. The main unit is not provided with a time switch, but only the exchange of the call slot on the time-division multiplexed frame between the connection device and the wireless terminal is performed. It is also possible to make a call exchange connection between and.
[0254]
Further, in the third embodiment, the number of control channels allocated to each wireless terminal is two. However, it is needless to say that three or more control channels may be used and an available control channel is selected from a plurality of allocated control channels. Then, interference may be avoided.
[0255]
Also, the number of control channels to be allocated to the wireless terminals does not necessarily need to be uniform, and many control channels may be allocated to wireless terminals having higher priorities depending on the priority of the wireless terminals.
[0256]
Further, in the third embodiment, the control channel in the time division multiplex frame between the connection device and the wireless terminal is used for one wireless terminal, but the control channel is used for controlling a plurality of wireless terminals. The slots may be used in a time-sharing manner.
[0257]
Furthermore, the configuration of the main unit, the connection device, the radio terminal, the radio configuration, the hardware configuration of the channel codec, the format of the radio frame (the number of control channels set to 20 in this embodiment, the number of multiplexed speech slots set to 4 in this embodiment) , Other detailed configurations of the control channel unit and the communication channel unit), a frequency hopping control method (the number of hopping frequencies assumed to be 20 in the present embodiment, etc.), a main device for control channel interference avoidance operation, a connection device, and a wireless terminal It is needless to say that the function assignment and the control command transmission / reception establishment determination condition and the specific interference avoidance operation procedure are not limited to the present embodiment, and can be changed without departing from the gist of the present invention.
[0258]
As explained above,According to the above embodimentBy providing a means for establishing an individual control channel between a predetermined number of wireless terminals and a connection device, and a means for assigning a plurality of control channels to the wireless terminals, the control channels are individually used for each wireless terminal. Control contention and control channel contention, reducing the time it takes to establish a wireless link.Can be shortened.
[0259]
Also,According to the above embodimentEven if one control channel becomes unusable due to interference, there is another pre-assigned control channel in place of the unusable control channel. Contention can be mitigated or prevented, and fast and effective control channel interference avoidance is achieved.Become possible.
[0260]
According to the above embodiment,, By assigning each of the control channels to a plurality of wireless terminals in a time-division manner, by assigning a plurality of control channels to one wireless terminal, a single connection device can be accommodated (ie, simultaneously controllable wireless terminals) Decrease the numberCan complement.
[0261]
According to the above embodiment,By assigning a different control channel to each wireless terminal, interference avoidance of the control channel can be prevented without affecting other wireless terminals when avoiding interference.Is possible.
[0262]
According to the above embodiment,By allocating one different control channel to each wireless terminal and allocating a plurality of common spare control channels to a plurality of wireless terminals, the control channel is more effective than when different control channels are allocated to each wireless terminal. The number of wireless terminals that can be accommodated in one connection deviceCan be increased.
[0263]
According to the above embodiment,In accordance with the priority of each wireless terminal, by assigning more control channels to wireless terminals with higher priorities, it is possible to avoid interference more with wireless terminals with higher priorityGreat potential.
[0264]
According to the above embodiment,By using one control channel at the same time among a plurality of control channels allocated for a wireless terminal, the number of control channels to be used can be reduced, and interference with other cells can be reduced.Can be deterred.
[0265]
According to the above embodiment,Means for determining that the control channel is unusable; and determining, from among control channels allocated to a certain wireless terminal, that the control channel originally used for the wireless terminal is unusable, the control being disabled. Means for selecting an available control channel from control channels pre-allocated to the wireless terminal in place of the channel and controlling the wireless terminal to use the selected control channel. The number of control channels to be used is reduced by appropriately using the available control channels, while suppressing interference with other cells.Avoid interference.
[0266]
According to the above embodiment,By using a plurality of control channels allocated for wireless terminals in parallel, it is not necessary to perform a process of changing the control channel, and the control channel can be quickly established.Avoid interference.
[0267]
According to the above embodiment,1. Differentiating the frequency of the time division multiplex frame between one connection device and the wireless terminal and the time division multiplex frame between the other connection device and the wireless terminal at the same time, thereby distinguishing each frame. At the same time, without interferenceCommunication is possible.
[0268]
According to the above embodiment,By switching the frequency of the time-division multiplex frame between the connection device and the wireless terminal within a predetermined time, that is, by performing frequency hopping, which is one type of spread spectrum, the interference rejection capability is enhanced,Can improve confidentiality.
According to the above embodiment, the frequency of the time-division multiplex frame between the connection device and the wireless terminal is switched for each frame period, that is, by performing frequency hopping which is one of spread spectrum systems, The removal capability is improved, the confidentiality is improved, and the frequency hopping is performed for each frame, so that the transmission and reception timing of the frame and the timing of the frequency hopping are integrated, thereby simplifying the circuit and control, and reducing the cost. There are also benefits.
[0269]
【The invention's effect】
According to the present invention,Since a different control channel is assigned to each wireless terminal,Reduce or prevent control channel contention and reduce time to connect wireless linksIn addition, since a plurality of control channels are assigned to each wireless terminal in advance, the control channels can be quickly switched.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing a system configuration according to a first embodiment of the present invention.
FIG. 2 is a block diagram illustrating a configuration of a main device of the first embodiment.
FIG. 3 is a block diagram illustrating a configuration of a connection device according to the first embodiment.
FIG. 4 is a block diagram showing a configuration of the wireless telephone according to the first embodiment.
FIG. 5 is a block diagram illustrating a configuration of a wireless adapter according to the first embodiment.
FIG. 6 is a block diagram illustrating a configuration of a wireless adapter with a built-in modem according to the first embodiment;
FIG. 7 is a block diagram illustrating a configuration of a wireless unit according to the first embodiment.
FIG. 8 is an explanatory diagram showing a frame format used in the first embodiment.
FIG. 9 is an explanatory diagram showing a frame format used in the first embodiment.
FIG. 10 is a block diagram illustrating a configuration of a channel codec according to the first embodiment.
FIG. 11 is an explanatory diagram showing a frequency hopping method used in the first embodiment.
FIG. 12 is an explanatory diagram showing an interference avoidance sequence due to control channel change due to inability of a wireless terminal to receive a control channel in the first embodiment.
FIG. 13 is an explanatory diagram showing an interference avoidance sequence due to control channel change due to inability to transmit a control channel in the connection device in the first embodiment.
FIG. 14 is a flowchart showing an operation of the main device of the first embodiment when avoiding interference.
FIG. 15 is a flowchart illustrating an operation of the connection device according to the first embodiment when interference is avoided.
FIG. 16 is a flowchart illustrating an operation of the wireless terminal according to the first embodiment when avoiding interference.
FIG. 17 is an explanatory diagram showing an interference avoidance sequence due to a control channel change due to the inability of the wireless terminal to receive a control channel in the second embodiment of the present invention.
FIG. 18 is an explanatory diagram showing an interference avoidance sequence due to a control channel change due to the inability of the wireless terminal to receive a control channel in the second embodiment.
FIG. 19 is an explanatory diagram showing an interference avoidance sequence due to control channel change due to inability of the control device to receive a control channel in the second embodiment.
FIG. 20 is an explanatory diagram showing an interference avoidance sequence due to a control channel change due to an inability to transmit a control channel in a connection device in the second embodiment.
FIG. 21 is a flowchart showing an operation of the main device of the second embodiment when avoiding interference.
FIG. 22 is a flowchart showing an operation of the main device of the second embodiment when avoiding interference.
FIG. 23 is a flowchart illustrating an operation of the connection device according to the second embodiment when interference is avoided.
FIG. 24 is a flowchart illustrating an operation of the wireless terminal according to the second embodiment when avoiding interference.
FIG. 25 is a block diagram illustrating a configuration example of a main device of a conventional wireless communication system.
FIG. 26 is a block diagram illustrating a configuration example of a connection device of a conventional wireless communication system.
FIG. 27 is a block diagram illustrating a configuration example of a wireless telephone set of a conventional wireless communication system.
FIG. 28 is an explanatory diagram showing an example of a transmission sequence of a conventional wireless communication system.
[Explanation of symbols]
1. Main device,
2. Connection device,
3 ... Wireless telephone,
4: Wireless adapter,
5 Data terminal,
7… Analog public line,
9 ... Digital public line,
10… Single phone,
11 ... Facsimile.

Claims (6)

In a wireless switching system that accommodates a plurality of wireless terminals,
Assigning means for assigning at least one control channel different for each wireless terminal as a first control channel, and for assigning a plurality of control channels to each wireless terminal in advance;
Determining means for determining that the control channel cannot be used;
Switching means for switching between communication control using the first control channel and communication control using another control channel previously allocated by the allocating means in accordance with the determination by the determining means that the first control channel is unusable;
A wireless switching system comprising: In claim 1,
The wireless switching system, wherein the assigning means assigns a plurality of different control channels to each of the wireless terminals . In claim 1 ,
The wireless switching system , wherein the allocating means allocates a control channel common to a plurality of wireless terminals to the wireless terminals in addition to the first control channel . In claim 1 ,
Wireless switching system said assigning means, in accordance with the priority order of the radio terminals, the high priority wireless terminals and allocates more control channels. In any one of claims 1 to 4 ,
Among a plurality of control channels allocated for the radio terminal, wireless switching system, characterized by the use only one control channel at the same time. In claim 1 ,
A wireless switching system comprising means for using a plurality of control channels allocated for wireless terminals in parallel.

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