JP3661342B2 - Communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a technical field of a communication apparatus that performs wireless communication by a frequency hopping method.
[0002]
[Prior art]
  Conventionally, in a communication system using the spread spectrum communication method, a communication method based on a frequency hopping method (hereinafter referred to as FH method) is used in order to effectively use a frequency and improve confidentiality. The FH system performs spreading by hopping a carrier according to a rule predetermined by a spreading code sequence. A transmission / reception apparatus in a conventional bidirectional communication system using the spread spectrum communication system based on the FH system is configured as shown in FIG. 9, for example.
[0003]
  First, when transmission is performed, a signal with a random frequency is output from the frequency synthesizer 206 in accordance with the spreading code sequence output from the spreading code sequence generator 205. On the other hand, the primary modulation signal is input to the transmission data input terminal 220, and the output frequency of the primary modulation signal is determined by the up-converter 203 based on the output from the frequency synthesizer 206. The transmission data frequency-converted by the up-converter 203 is amplified by the amplifier 208, and then transmitted from the antenna 211 via the duplexer 210.
[0004]
  Next, when reception is performed, the signal received by the antenna 211 is separated from the transmission wave by the duplexer 210, amplified by the amplifier 209, and then input to the down converter 207. Then, the frequency is converted by the down converter 207 based on the signal designating the frequency from the frequency synthesizer 206, and demodulated by the demodulator 212 to be received data. The received data is output to a data operation circuit (not shown) and also output to the synchronization circuit 204. The synchronization circuit 204 detects the phase of the hopping frequency from the received signal, and outputs the synchronization signal from the synchronization circuit 204 to the spreading code sequence generator 5. The spreading code sequence generator 205 outputs a spreading code sequence in accordance with the input synchronization signal. The spreading code sequence output from the spreading code sequence generator 205 is supplied to the frequency synthesizer 206, and the frequency synthesizer 206 is input. A random frequency output is generated according to the spread code sequence.
[0005]
  The down converter 207 multiplies the received signal by the output from the frequency synthesizer 206 to despread the received signal. The despread signal despread in the down converter 207 is demodulated by the demodulator 212, and the demodulated reception data is output from the reception data output terminal 221.
[0006]
  Two-way communication is performed by simultaneously operating the transmission unit and the reception unit as described above.
[0007]
  The random frequency means that the spreading code output every time a synchronization signal is input from the spreading code generator 205 is changed randomly, and a set of spreading code sequences (frequency hopping patterns) is set. Transmission and reception are performed by sharing the communication devices.
[0008]
  As a specific example of a device using such a communication method, there is a cordless telephone device using the communication method for communication between a parent device and a child device. In recent years, only a child device is used as a voice terminal. Rather, the handset and personal computerEtc.Some of them are used as data terminals by connecting.
[0009]
[Problems to be solved by the invention]
  However, in the conventional apparatus, the period of communication by hopping the frequency is the same regardless of whether it is voice data or non-voice data, so that efficient communication cannot be performed. There was a problem.
[0010]
  For example, since communication data handled by a personal computer or the like requires a high data transmission / reception rate, it is necessary to lengthen the communication period. However, when audio data is transmitted / received in such a long communication period, there is a problem that, when an interference with a specific frequency occurs, the sound cannot be heard during the communication period using that frequency. In addition, the advantage of the frequency hopping method that increases confidentiality is impaired.
[0011]
  On the other hand, if the period of communication by hopping the frequency is shortened according to the voice data, an occupation period for stabilizing the frequency is required every time the frequency is hopped. Etc., the data transmission rate is lowered.
[0012]
  Therefore, it is possible to prepare both a long period and a short period as a period for hopping the frequency and select either according to the type of data. Therefore, the number of frequencies hopped within a predetermined time differs. As a result, in the base unit of the cordless telephone apparatus that handles both the communication data and the voice data, for example, when communication is performed in a short period after performing communication using a long period, synchronization cannot be achieved. Therefore, it is necessary to perform complicated control in the transmission / reception apparatus.
[0013]
  In addition, when there are multiple devices that handle communication data, and when the devices communicate with each other, it is necessary to synchronize with the parent device at the end of the communication. It is also necessary to perform communication between the devices at a timing synchronized with the communication timing between the parent device and the device.
[0014]
  However, when calling from one device to another device, if the same frequency as that used for communication with the parent device is used, communication between the parent device and the other device will occur. The communication is disturbed by calling.
[0015]
  In addition, since all devices are switched in frequency by synchronizing with the parent device, they cannot be called at different frequencies.
[0016]
  Therefore, conventionally, the communication between the devices can be performed only after the communication request between the devices is once transmitted from the device to the parent device and permission is obtained from the parent device.
[0017]
  The present invention has been made in view of the above-described problems, and performs efficient communication with a simple configuration in a communication apparatus that performs both voice data and non-voice data communication using a frequency hopping method. It is an object of the present invention to provide a communication device that can perform communication between slave units easily.
[0018]
[Means for Solving the Problems]
  In order to solve the above-described problem, the communication device according to claim 1 includes a frame switching unit that switches a frame that is a unit of communication, a frequency selection unit that selects a frequency corresponding to the switched frame, and one frame Transmission / reception timing control means for controlling transmission / reception timing so as to be divided into a transmission / reception waiting period for frequency stabilization and a transmission / reception execution period for data transmission / reception, and data transmission / reception at the transmission / reception timing by the selected frequency A frequency hopping communication device provided with at least a base unit and a non-voice data slave unit each including a wireless transmission / reception unit, wherein the base unit serves as the frequency selection unit each time the frame is switched. Means for selecting a frequency corresponding to the transmission / reception execution period in a predetermined order; The data slave unit provides, as the transmission / reception timing control means, a transmission / reception execution period synchronized with the transmission / reception execution period of the master unit, and other non-voice data in a period after the transmission / reception execution period in one frame. When a call response period is provided between the slave unit and communication with other slave unit for non-speech data is performed, the non-speech slave unit synchronized between the slave units for non-speech data in the frame Means for providing a transmission / reception execution period for use, and, as the frequency selection means, in the transmission / reception execution period synchronized with the transmission / reception execution period of the base unit, the same frequency as the frequency corresponding to the transmission / reception execution period of the base unit Are selected in the same order, and when communicating with the other non-speech data slave unit, the frequency used for communication between the master unit and the slave unit in the non-speech slave transmission / reception execution period Choose a different frequency And means forAs,The transmission / reception timing control means of the non-audio data slave unit makes the length of the transmission / reception execution period variable according to a request from the master unitIt is characterized by that.
[0019]
  According to the communication device of the first aspect, when the frame is switched by the frame switching unit in the base unit, the frequency corresponding to the transmission / reception execution period is selected by the frequency selection unit in a predetermined order. The frame is divided into a transmission / reception standby period and a transmission / reception execution period by the transmission / reception timing control means. In the transmission / reception standby period, transmission / reception is not performed for stabilization of the selected frequency. Thus, data transmission / reception is performed. On the other hand, in the non-audio data slave unit, the transmission / reception timing control unit controls the transmission / reception execution period in the slave unit to be synchronized with the transmission / reception execution period of the master unit, and the frequency selection unit controls the transmission / reception unit. The same frequency as that corresponding to the execution period is selected in the same order. Therefore, since the master unit and the non-voice data slave unit perform data transmission / reception at the same transmission / reception timing and the same frequency, transmission / reception between the master unit and the non-speech data slave unit is performed reliably.
[0020]
  When communication between the non-voice data slave units is started, a call response period is provided in the period after the transmission / reception execution period in one frame by the transmission / reception timing control unit, and the radio transmission / reception unit During the call response period, a call to another non-voice data slave unit and a response from the other non-voice data slave unit are performed.
[0021]
  Therefore, even when communication is performed between another non-voice data slave unit and the master unit, the call and response between the non-voice data slave units are provided after the transmission / reception execution period. Since the communication is performed during the call response period, the call and response between the other non-voice data slave units without interfering with the communication between the other non-voice data slave unit and the master unit, Is done.
[0022]
  As a result of the response, when communication between the non-voice data slave units is performed, a non-voice slave unit transmission / reception execution period synchronized between the non-voice data slave units by the transmission / reception timing control means The frequency selection means selects a frequency different from the frequency used for communication with the parent device during the non-voice child device transmission / reception execution period. As a result, communication between the non-voice data slave units is performed independently of the master unit and other non-speech data slave units, and the communication capacity of the entire system increases.
  Moreover, since the length of the transmission / reception execution period in the non-voice data slave unit is variable according to the request from the master unit, the transmission rate of non-voice data is improved according to the situation, or the transmission / reception of non-voice data is performed. It is possible to efficiently perform processing and other processing such as calling and response processing.
[0023]
  The communication device according to claim 2 is the communication device according to claim 1, wherein a frame switching unit that switches a frame that is a unit of communication, a frequency selection unit that selects a frequency corresponding to the switched frame, Transmission / reception timing control means for controlling transmission / reception timing so as to divide one frame into a transmission / reception standby period for frequency stabilization and a transmission / reception execution period for data transmission / reception, and data at the transmission / reception timing by the selected frequency Radio data transmission / reception means for performing transmission / reception is further provided in the voice data slave unit. When the master unit performs communication with the voice data slave unit as the transmission / reception timing control means, the transmission / reception standby period and the transmission / reception unit In addition to the execution period, the one frame is included in the transmission / reception standby period for voice slaves and the transmission / reception execution period for voice slaves. And a means for selecting, as the frequency selection means, a frequency different from the frequency at the time of frame switching in a predetermined order when the transmission / reception standby period for the voice slave unit is provided. The audio data slave unit includes, as the transmission / reception timing control unit, a unit for controlling a transmission / reception execution period in the slave unit in synchronization with the transmission / reception execution period for the voice slave unit, and further, as the frequency selection unit, A means for selecting the same frequency as the frequency corresponding to the transmission / reception execution period for the voice slave unit in the same order is provided.
[0024]
  According to the communication device according to claim 2, when communication is performed between the master unit and the voice data slave unit, the transmission / reception timing control unit of the master unit transmits the frame, the transmission / reception standby period, and the transmission / reception unit. In addition to the execution period, in addition to these periods, the voice slave transmission / reception standby period and the voice slave transmission / reception execution period are divided. In addition, the frequency selection means is predetermined as a frequency corresponding to the transmission / reception execution period for the voice slave unit, a frequency different from the frequency corresponding to the transmission / reception execution period for performing communication with the non-voice data slave unit Select in order. Therefore, the wireless transmission / reception means communicates with the non-voice data slave unit at a predetermined frequency during the transmission / reception execution period, and at the frequency different from the frequency at the voice slave unit transmission / reception execution period. And communication with the audio data slave unit. On the other hand, in the audio data slave unit, the transmission / reception execution period in the slave unit is controlled in synchronization with the transmission / reception execution period for the voice slave unit by the transmission / reception timing control unit, and the voice slave unit is controlled by the frequency selection unit. The same frequency corresponding to the transmission / reception execution period is selected in the same order. Thereby, since the master unit and the voice data slave unit perform data transmission / reception at the same transmission / reception timing and the same frequency, transmission / reception between the master unit and the voice data slave unit is reliably performed. In addition, the transmission / reception execution period for the voice slave unit is provided within the frame in addition to the transmission / reception execution period used for communication with the slave unit for non-voice data. Communication between the slave unit and the master unit and the voice data slave unit is performed by time division within one frame. Therefore, since communication between the parent device and the non-voice data slave device and communication between the parent device and the voice data slave device are performed at different timings and different frequencies, the mutual communication is not disturbed. Furthermore, the communication between the non-voice data slave units does not interfere with the communication between the master unit and the voice data slave units and between the voice data slave units. The communication between the master unit and the non-voice data slave unit and the communication between the non-speech data slave units are not disturbed. In addition, since the call and response between the non-voice data slave units are also performed at a different frequency from the frequency used for the communication of the voice data slave units, the voice data slave units can communicate with each other. There is no interference.
[0025]
  The communication device according to claim 3 is the communication device according to claim 1 or 2, wherein the frequency selection means of the non-voice data slave unit is connected to the other non-voice data slave unit. The communication apparatus according to claim 1, wherein a frequency in a paging response period is the same as a frequency in the transmission / reception execution period.
[0026]
  According to the communication device of claim 3, the call and response between the non-voice data slave unit and the other non-voice data slave unit are performed at the same frequency as the frequency in the transmission / reception execution period. Therefore, the frequency hopping synchronization with other devices is maintained even after the call and response processing without performing complicated hopping data control.
[0027]
[0028]
[0029]
  Claim4The communication device according to claim 1 to claim 1.3In the communication device according to any one of the above, the transmission / reception timing control means of the non-voice data slave unit may set the transmission / reception execution period to be longer than a call response period with the other non-voice data slave unit. Characterized by lengthening.
[0030]
  Claim4Since the transmission / reception execution period in the non-voice data slave unit is longer than the call response period, data transmission / reception is performed at a high data transmission rate.
[0031]
  Claim5The communication device according to claim 1 to claim 1.45. The communication device according to claim 1, wherein the transmission / reception timing control unit of the non-voice data slave unit includes the master unit in the frame after communication between the non-voice data slave units of a predetermined number of frames. A transmission / reception execution period synchronized with the transmission / reception execution period is provided.
[0032]
  Claim5According to the communication device described in the above, when the communication between the non-voice data slave units is performed for a predetermined number of frames, a transmission / reception execution period synchronized with the transmission / reception execution period of the master unit is provided thereafter. Communication between the non-voice data slave units is not continued over a long period of time, and communication with other devices is performed efficiently.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments embodying the present invention will be described below with reference to FIGS. FIG. 1 is a block diagram showing a schematic configuration of a master unit and a slave unit constituting a communication device according to an embodiment of the present invention. FIG. 2 is a block diagram showing a schematic configuration of a wireless communication unit used in the communication device of FIG. is there.
[0034]
  As shown in FIG. 1, the communication apparatus according to the present embodiment is connected to a general commercial analog telephone line by wire, and has a master unit 1 having a printer function, a facsimile function, and a master-slave telephone function, and further, the master unit 1 and frequency hopping. Wirelessly connected three voice terminals 3a to 3c, three data terminals 6a to 6c such as personal computers, and the data terminals 6a to 6c are wired to the base unit 1 and frequency hopping. It is composed of three wireless adapters 4a, 4b, and 4c as non-voice data slave units that are wirelessly connected by the system.
[0035]
  First, the configuration of base unit 1 will be described. The master unit 1 is a multi-function device having a scanner function, a facsimile function, a print function, and a master-slave phone function, and wireless communication as a wireless transmission / reception means for performing frequency hopping wireless communication described later with the slave unit. An image reading unit comprising: a unit 11; an image output unit 12 that forms an image on a recording material; a buffer 12a that temporarily stores image data output to the image output unit 12; and a scanner. 13, a buffer 13 a that temporarily stores image data output from the image reading unit 13, and coded audio data that is wirelessly communicated by the wireless communication unit 11 and audio data that is externally communicated Between the audio conversion unit 14 and the wireless communication unit 11 or the image data output from the image reading unit 13 or A data conversion unit 15 that performs mutual conversion between image data output to the image output unit 12 and non-speech data that is communicated outside, and temporarily stores data handled by the data conversion unit 15 A buffer 15a, a line control unit 16 connected to a plurality of external lines 8 and 9, and a switching unit 17 for switching input / output destinations of non-audio data such as image data transmitted / received via the wireless communication unit 11; It has. Note that an operation unit including a switch for operating the parent device 1 is not shown.
[0036]
  Next, the structure of each part which comprises the above main | base stations 1 is demonstrated in detail.
[0037]
  As shown in FIG. 2, the wireless communication unit 11 includes a modem 51 that demodulates or modulates data handled by the voice conversion unit 14 or the data conversion unit 15 and data that is wirelessly transmitted / received, and the modem 51 An up-converter 52 that converts the output signal to a communication frequency, a power amplifier 53 that amplifies the signal output from the up-converter 52, a transmission / reception switch 54 that switches between transmission and reception, an antenna 55, A low-noise amplifier 56 that amplifies the received signal, a down-converter 57 that converts the frequency of the signal output from the low-noise amplifier 56 and outputs the converted signal to the modem 51, and the up-converter 52 and down-converter 57 for the conversion. The PLL local oscillator 58 that outputs the frequency of and the PLL local oscillator 58 that outputs the frequency The hopping table 59 in which the hop frequency data described above is recorded, the controller 60 for selecting the frequency to be output from the hopping table 59 to the PLL local oscillator 58, and the information on the frequency to be selected for the controller 60 are sequentially switched. A hopping counter 61 for instructing, a frame counter 62 for outputting a reference signal for an instruction operation of the hopping counter 61, and a clock 63 for supplying a reference clock to the frame counter 62 are provided.
[0038]
  In the above configuration, for example, when image data input via the external line 8 and the data converter 15 is output to the modem 51, the image data is modulated into an intermediate frequency signal by the modem 51, and the up-converter Is output to 52.
[0039]
  The up-converter 52 includes a mixer, and multiplies the intermediate frequency signal output from the modulator / demodulator 51 by the oscillation frequency signal output from the PLL local oscillator 58 to obtain the frequency of the intermediate frequency signal and the oscillation frequency signal. It converts into the frequency signal for communication which has the sum frequency. The frequency conversion does not need to be performed in one stage, and may be a two-stage configuration using another local oscillator.
[0040]
  The communication frequency signal converted by the up-converter 52 is amplified by the power amplifier 53, and the amplified signal is transmitted from the antenna 55 through the transmission / reception switch 54.
[0041]
  The signal received by the antenna 55 is sent to the receiving side by the transmission / reception switch 54, amplified by the low noise amplifier 56, and output to the down converter 57.
[0042]
  The down-converter 57 also includes a mixer, similar to the up-converter 52, and by multiplying the oscillation frequency signal output from the PLL local oscillator 58 and the received signal, the frequency difference between the reception signal and the oscillation frequency signal is obtained. Is converted to an intermediate frequency signal having a frequency of. The oscillation frequency signal output from the PLL local oscillator 58 is converted into an intermediate frequency signal by subtracting it from the received signal. On the receiving side, the frequency conversion does not have to be performed in one stage, and may be a two-stage configuration using another local oscillator.
[0043]
  The intermediate frequency signal converted by the down converter 57 is output to the modem 51, demodulated by the modem 51, and output to the outside line through the data converter 15 and the line controller 16, for example, as image data.
[0044]
  The frame counter 62 that has determined that a predetermined time has elapsed from the start of transmission / reception by counting the output from the clock 63 increments the hopping counter 61 and outputs it to the controller 60. The controller 60 selects a frequency from the hopping table 59 based on the incremented counter value and outputs it to the PLL local oscillator 58. Thereby, the frequency of the signal transmitted / received is hopped one after another at the predetermined hopping timing, and wireless communication with high confidentiality and high frequency utilization efficiency is performed.
[0045]
  FIG. 4 is a diagram showing the contents of the hopping table. In FIG. 4, M indicates the counter value of the hopping counter 61, and f indicates the hopping frequency. For example, when M = 0, f = f₀When M = 1, f = g₀Is selected.
[0046]
  The operation control and power on / off control as described above are performed by the controller 60, and the controller 60 functions as a frame switching means, a frequency selection means, or a transmission / reception timing control means.
[0047]
  Next, the image output unit 12 is means for outputting an image of data stored in the buffer. For example, a means using a photosensitive drum by an electrophotographic method, a thermal transfer means using a thermal head, or an inkjet head is used. It is comprised by the means provided. The data stored in the buffers 12a and 15a includes network communication data or image data transmitted from the data terminals 6a, 6b and 6c via the wireless adapters 4a, 4b and 4c, or transmitted from the outside line. It is.
[0048]
  The image reading unit 13 includes a scanner or the like, and image data read by the scanner or the like is temporarily stored in the buffer 13a and output to the image output unit 12 or via the wireless communication unit 11. Used for wireless communication.
[0049]
  The audio conversion unit 14 is composed of a codec and a compressor that perform mutual conversion between audio and digital signals under the control of a CPU (not shown), and converts audio data that is digitally encoded and transmitted from the slave units 3a to 3c. The analog data is converted into analog data and output to the line control unit 16, and the analog voice data received via the line control unit 16 is digitally encoded for transmission to the slave units 3a to 3c.
[0050]
  The data conversion unit 15 includes a buffer that handles digital non-sound data output from a personal computer or the like or an image signal such as a FAX signal, a data converter that performs error correction processing, and the like. In order to realize the terminal characteristics and the transmission procedure, data compression is performed by an MH (Modified Huffman) method or the like, a binary code signal method using an HDLC frame is adopted, and data is transmitted at a transmission rate of 14400 bps.
[0051]
  A line control unit 16 for performing external line control is connected to the external lines 8 and 9, and signals from the external lines 8 and 9 are converted to the voice conversion unit 14 or the data conversion by the control of a CPU (not shown). The data is output to any one of the units 15, and the data output from the voice conversion unit 14 or the data conversion unit 15 is transmitted by any one of the external lines 8 and 9.
[0052]
  The switching unit 17 includes switching means for switching the connection destination in the base unit of the wireless communication unit 11. When the connection destination is switched to the buffer 15 a side, the switching unit 17 is connected via the wireless communication unit 11. External line communication is performed by the slave unit. Further, when the connection destination is switched to the buffer 12a or the buffer 13a side, the image data read by the image reading unit 13 is transmitted to the data terminals 6a to 6c via the wireless communication unit 11, and the data The image output unit 12 forms an image based on the image data transmitted from the terminals 6a to 6c.
[0053]
  Next, the configuration of the audio terminal slave units 3a to 3c will be described.
[0054]
  The cordless handsets 3a to 3c are cordless telephones and, as shown in FIG. 1, include antennas 31a to 31c, and wireless communication units 32a to 32c as wireless transmission / reception means having the same configuration as the wireless communication unit 11 described above. Similarly to the voice conversion unit 14 described above, voice conversion units 33a to 33c having an A / D conversion function are provided. Moreover, although illustration is abbreviate | omitted, the subunit | mobile_unit 3a-3c is provided with the microphone and speaker for inputting / outputting an audio | voice.
[0055]
  The configuration of the wireless communication units 32a to 32c is the same as the configuration of the wireless communication unit 11, and the description thereof is omitted. However, the data handled in the wireless communication units 32a to 32c is only audio data.
[0056]
  In the configuration as described above, the sound input from the microphone is converted into, for example, a 19200 bps digital signal in the sound conversion units 33a to 33c, and then digitally encoded and output to the wireless communication units 32a to 32c. . And in the radio | wireless communication parts 32a-32c, it transmits from the antennas 31a-31c by the above-mentioned frequency hopping system. On the other hand, the signals received by the antennas 31a to 31c are output from the radio communication units 32a to 32c to the audio conversion units 33a to 33c, decoded by the audio conversion units 33a to 33c, and then converted to analog audio signals. And output to the speaker. The control of each unit is performed by a CPU (not shown).
[0057]
  Next, the configuration of the wireless adapters 4a to 4c as the non-voice data terminal slave units will be described. The wireless adapters 4a to 4c are connected to data terminals 6a to 6c that handle non-voice data such as personal computers or PDAs (Personal Digital Assistants), and are equipped with antennas 41a to 41c as shown in FIG. Wireless communication units 42 a to 42 c as wireless transmission / reception means having the same configuration as the wireless communication unit 11 and data conversion units 43 a to 43 c having the same configuration as the data converter 15 described above.
[0058]
  The configuration of the wireless communication units 42a to 42c is the same as the configuration of the wireless communication unit 11, and the description thereof is omitted. However, the data handled in the wireless communication units 42a to 42c is only non-voice data.
[0059]
  Image data or text data output from the data terminals 6a to 6c is converted as data for wireless communication by the data converters 43a to 43c, and is transmitted to the base unit 1 by the wireless communication units 42a to 42c by a frequency hopping method. Wirelessly transmitted. The data transmitted from the base unit 1 and received by the wireless communication units 42a to 42c is converted into image data or text data by the data conversion units 43a to 43c, and transmitted to the data terminals 6a to 6c. The control of each part is performed by a CPU (not shown).
[0060]
  The communication apparatus according to the present embodiment can perform data reception such as FAX reception, FAX transmission, telephone communication, and personal computer in the configuration as described above, and each communication is performed in the following combinations.
[0061]
  A. FAX reception: external line 9 → base unit 1 → image output unit 12
  B. FAX transmission: image reading unit 13 → base unit 1 → external line 9
  C. Telephone communication: External line 8 ← → Base unit 1 ← → Slave units 3a to 3c
  D. Data communication: data terminals 6a-6c ← → wireless adapters 4a-4c ← → parent
                  Machine 1 ← → External line 9
  E. Extension communication 1: handset 3a-3c ← → handset 3a-3c
  F: Extension communication 2: Data terminals 6a-6c ← → Wireless adapters 4a-4c ← → No
                  Line adapters 4a to 4c ← → data terminals 6a to 6c
  As described above, in the communication apparatus of this embodiment, voice data, FAX data, and non-voice data input / output from a personal computer or the like are handled, but these data have different properties.
[0062]
  In other words, for audio data, the communication speed may be slow, but real-time two-way communication is necessary, and it is necessary to prevent hearing problems due to radio wave interference. For FAX data, there is no need for real-time two-way communication at a data rate of about 14.4 kbps. Furthermore, high-speed non-voice data input / output from a personal computer or the like requires high throughput by high-speed transfer or packet communication, and requires a data rate of 64 kbps or higher.
[0063]
  However, in the wireless communication based on the frequency hopping method as described above, time is required to stabilize the frequency at the time of hopping, and the data rate is affected by the number of hops per unit time.
[0064]
  In other words, if the number of hops per unit time is large, the data rate will be low, which is inappropriate for the high-speed non-voice data as described above, and conversely if the number of hops per unit time is small. However, if one frequency is disturbed while the data rate is increased, it causes a hearing loss that can be recognized by hearing, which is not preferable.
[0065]
  In addition, when the configuration is such that only the number of hops per unit time is changed according to the type of data, the hopped frequency cannot be synchronized between devices. In the base unit 1 that handles both data, the configuration of the wireless communication unit 11 becomes complicated.
[0066]
  Therefore, in the present embodiment, frequency hopping is performed in units of frames, and when transmitting or receiving non-voice data and sending / receiving voice data within one frame, the frequency is also transmitted before sending / receiving voice data. Configured to do hops.
[0067]
  Specifically, as shown in FIG. 3, the frame in the base unit 1 includes a first hop slot 70 that is a transmission / reception standby period, and a data slot 71 that is a transmission / reception execution period for transmitting or receiving non-voice data. The second hop slot 72, which is a transmission / reception standby period for voice slaves, and the voice slot 75, which is a transmission / reception execution period for voice slaves for transmitting / receiving voice data. The audio slot 75 is divided into a transmission slot 73 and a reception slot 74.
[0068]
  In the voice data slaves 3 a to 3 c, one frame from the hop slot 80, the sleep slot 81, the wake slot 82, and the voice slot 85 that starts waiting for transmission and reception at the timing synchronized with the hop slot 70. Is configured. The length of the frame is the same as that of the parent device, and the audio slot 85 is divided into a reception slot 83 and a transmission slot 84 so as to be synchronized with the frame of the parent device.
[0069]
  Further, in the wireless adapters 4a to 4c which are the slave units for non-voice data, the hop slot 90 which starts waiting for transmission / reception at the timing synchronized with the hop slot 70 and the transmission / reception of non-voice data are synchronized with the master unit. And a call response slot 92 as a call response period for calling and responding to other wireless adapters. The length of the frame is the same as that of the main unit.
[0070]
  The hop slots 70, 72, 80, and 90 shown in FIG. 3 are periods for stabilizing the hopped frequency, and data transmission / reception is not performed during this period.
[0071]
  However, the hop slot 80 of the slave units 3a to 3c is configured to be longer than the hop slots 70 and 72 of the master unit 1 or the hop slot 90 of the wireless adapters 4a to 4c, and does not overlap the voice slot 85. Can take long enough. This is because the voice slots 85 in the slave units 3a to 3c are provided in the second half of the frame, and by configuring in this way, a margin is provided for the frequency stabilization time of the PLL local oscillator 58. This eliminates the need for an expensive high-speed PLL local oscillator.
[0072]
  The data slots 71 and 91 are used for transmission / reception of FAX data with a data rate of about 14.4 kbps and high-speed non-voice data with 64 kbps or higher. The data slots 71 and 91 have the length of the period T1 as shown in FIG. 3A when communication is performed between the master unit 1 and the voice terminal slave units 3a to 3c. When communication with the voice terminal slave units 3a to 3c is not performed, the length is changed to the length of the period T2, as shown in FIG. Such data slot length change information is transmitted from the base unit 1 to the wireless adapters 4a to 4c. Also, as will be described later, when performing communication between wireless adapters, a data slot 91 having a length of a period T2 as shown in FIG.
[0073]
  The voice slots 75 and 85 are used for voice data transmission of 32 kbps or 64 kbps or less. However, since a real-time communication is necessary for a voice slot, transmission / reception is switched using TDD (Time Division Duplex).
[0074]
  In the sleep slot 81, if only the timer for measuring time is operated, most of the power of the wireless communication unit can be turned off. Thereby, power consumption can be reduced. After the sleep slot 81 ends, the power is turned on in the wake slot 82 to prepare for communication.
[0075]
  In this embodiment, communication is performed using a frame having the above-described structure. As shown in FIG. 3, the frequency hop is determined by the timing t0 at which the frame is switched and the data slot 71 in the base unit 1. It was decided to carry out at the timing t1 to end. In addition, the hop at the timing t0 and the hop at the timing t1 are performed using a hop table composed of different frequency data strings.
[0076]
  Also, in the voice slave terminals 3a to 3c, a frequency hop is performed at t0 which is equal to the frame switching timing of the parent device, and the frequency table used for this hop is used when hopping at the timing t1 in the parent device. A table having the same frequency data string as the table was used.
[0077]
  Further, in the wireless adapters 4a to 4c, in order to synchronize with the parent device, a frequency hop is performed at the frame switching timing t0, and a table used for the hop at the timing t0 of the parent device is included in the table used for this hop. The same table was used.
[0078]
  Specifically, the table shown in FIG. 4A is used for transmission or reception using the data slot of the parent device. This table is f₀~ F_mA frequency data string consisting of and g₀~ G_mAre alternately arranged, and according to the value M of the hopping counter 61, f₀, G₀, f₁Selected in order. Note that the frequency data of these frequency data strings are randomly arranged.
[0079]
  In addition, when M = 2m + 1, the base unit does not read the hopping table from the output of the hopping counter 61, so that the frequency hop is performed only once in one frame as shown in FIG. 3B. Can be.
[0080]
  In the wireless adapters 4a to 4c, the table shown in FIG. This table is f₀~ F_mA frequency data string consisting of
[0081]
  Further, the table shown in FIG. 4C is used in the voice slave terminals 3a to 3c. This table is g₀~ G_mA frequency data string consisting of
[0082]
  And the table of FIG.4 (d) is a table used for communication between audio | voice cordless handsets, FIG.4 (e) is a table used for communication between wireless adapters.
[0083]
  In order to perform communication between the voice slave units, it is necessary to call another voice slave unit from one voice slave unit and confirm a response from the other voice slave unit. If this is done, there is a risk of hindering communication between another voice slave and the master.
[0084]
  Therefore, in this embodiment, the call and response are performed in the sleep slot 81. By using the sleep slot 81, there is no fear of interfering with communication between another voice slave unit and the master unit, and the frequency used for the voice slave unit communication and the frequency used for the wireless adapter communication are shown in FIG. ) And (c) are different from each other, so that the communication between the wireless adapter and the base unit or the communication between the wireless adapters is not hindered by the call and response.
[0085]
  When communication is enabled by calling and answering, the table shown in FIG. 4 (d) is used to prevent communication between the voice slave units without interfering with communication between another voice slave unit and the master unit. Communication is performed.
[0086]
  On the other hand, when communicating between wireless adapters, it is necessary to call and respond in the same way as a voice slave unit. However, as with a voice slave unit, communication between another wireless adapter and the master unit is hindered. There is no need to do so.
[0087]
  Therefore, in the present embodiment, as shown in FIG. 3A, a call response slot 92 is provided after the data slot 91, and a call and response with another wireless adapter is performed by the call response slot 92. It was configured as follows.
[0088]
  By using this call response slot 92, it is possible to perform a call and response between wireless adapters without interfering with communication between another wireless adapter and the parent device.
[0089]
  Further, when shifting to the call response slot 92, no frequency hop is performed. That is, a call and a response are performed at the same frequency as that used in the data slot 91. Thus, communication between the voice slave unit and the master unit or the voice slave unit is not hindered.
[0090]
  When communication is enabled by calling and responding, communication is performed using the table shown in FIG. 4E, so that communication between another wireless adapter and the base unit is not hindered. Communication. Further, when communication between wireless adapters is performed, the length of the data slot 91 is extended to the period T2, as shown in FIG. Thereby, the amount of data transmission can be increased and the data rate can be increased.
[0091]
  Next, the communication processing in the present embodiment will be specifically described based on the timing chart of FIG. 5 and the flowcharts of FIGS.
[0092]
  FIG. 6 is a flowchart showing communication processing of the base unit 1, FIG. 7 is a flowchart showing communication processing of the voice slave unit, and FIG. 8 is a flowchart showing communication processing of the wireless adapter.
[0093]
  First, a case where the parent device 1 is communicating with the voice child device 3a and further communicates with the wireless adapter 4a will be described. In FIG. 5A, the frame Fa1 and subsequent frames are shown, but the description will be made assuming that communication has been performed before the frame Fa1. Further, the description will be made assuming that a call is made from the wireless adapter 4a to the base unit 1 before the frame Fa1. First, when the frame before the frame Fa1 shown in FIG. 5A ends, the frame is switched at the timing of time t0, and the frequency hop is performed at this timing (FIG. 6; step S1). If the value M of the hopping counter 61 at this time is 0, the controller 60 calculates the frequency f from the table shown in FIG.₀Select. Then, if there is a communication request from the wireless adapter 4a and transmission from the wireless adapter 4a is performed, this is not the case where the parent device performs transmission (step S2; NO), so the frequency f₀Then, communication with the wireless adapter 4a is performed in the data slot (step S3). In the case of FIG. 5A, a transmission permission signal is transmitted from the parent device 1 to the wireless adapter 4a.
[0094]
  Then, after the end of the data slot, the value M of the hopping counter 61 is incremented at the time t1 shown in FIG. 5A, and the frequency hop is performed again (step S9). At this time, since the value M of the hopping counter 61 is 1, the frequency g is determined from the table shown in FIG.₀Is selected and this frequency g₀Thus, communication between the master unit and the voice slave unit is performed (step S10).
[0095]
  On the other hand, the voice handset 3a also hops at time t0 in the same manner as the base unit 1 (FIG. 7; step S31), but the hopping table used in the voice handset is the table shown in FIG. = 0, frequency g₀Is selected. And since it is communicating now and it is not the mode which calls a subunit | mobile_unit (step S32; YES-step S33; NO), it transfers to a standby state (step S34). In the present embodiment, as described above, the sleep slot is provided in this standby state, and the slave unit 3a is in the sleep state until the hop at the time t1 in the master unit is performed. Next, the wake state is entered at the timing of time t1 to prepare for communication with the parent device from time t2. Then, since there is no incoming call from another voice slave (step S35; NO) and it is not the mode for calling the master (step S37; NO), communication with the master is performed (step S39).
[0096]
  The wireless adapter 4a also hops at time t0 in synchronization with the parent device 1 (FIG. 8; step S70). Since the table in the wireless adapter 4a is the table shown in FIG. 4B, when M = 0, the frequency f₀Is selected. Since communication with other wireless adapters is not performed (step S71; NO), the frequency f₀In step S76, data from the parent device is received by the data slot.
[0097]
  Since this data is a transmission permission signal as described above and there is no transmission from another wireless adapter (step S77; NO), transmission from the wireless adapter 4a to the base unit 1 is performed (step S79; YES to step). S80).
[0098]
  Thereafter, when the same processing is continued in the frames Fa1 to Fa4 as shown in FIG. 5A, the frequency is f in the data slot of the base unit 1.₀, f₁, f₂, f_ThreeHopped and g in the voice slot₀, g₁, g₂, g_ThreeSince the hop is also performed in the voice handset 3a and the wireless adapter 4a, communication between the base unit and each handset is performed reliably.
[0099]
  In particular, in the master unit 1 and the voice slave unit 3a, transmission and reception are alternately performed within one frame. By repeating this, continuous transmission / reception of voice signals is performed.
[0100]
  The base unit 1 and the wireless adapter 4a transmit and receive packet data. As shown in FIG. 5A, either one of transmission and reception is performed in one data slot.
[0101]
  Next, a case where data is transmitted from the wireless adapter 4c to the wireless adapter 4b will be described. In this case, first, it is necessary to make a call from the wireless adapter 4c to the wireless adapter 4b. As described above, this call is made by the call response slot 92. Further, a response from the wireless adapter 4b is also made by the call response slot 92. Hereinafter, processing between wireless adapters will be described with reference to the flowcharts of FIGS.
[0102]
  First, the wireless adapter 4c hops to the frequency f1 at the time t3 shown in FIG. 5A (FIG. 8; step S70), and is not communicating with other wireless adapters (step S71; NO). From time to time t5 in the data slot (step S76). However, there is no transmission from the other wireless adapter (step S77; NO), and no transmission to the parent device is performed (step S79; NO), and the process proceeds to a calling process to the other wireless adapter (step S81; YES). ). First, in the call response slot from time t5 to time t6, a call is made to the wireless adapter 4b without performing a frequency hop (step S82). Then, at the timing of time t6, the frequency f₂(Step S83), wait until time t7 when the data slot ends, and determine whether or not there is a response from the wireless adapter 4b (step S84). As a result, when there is no response (step S84; NO), it hops to the next frequency (step S85) and repeats the above-described calling and response waiting (steps S82 to S84).
[0103]
  On the other hand, when there is a response from the wireless adapter 4b in the paging response slot from time t7 to time t8 (step S84; YES), the hop table is switched to the table shown in FIG. 4 (e), and at the timing of time t8. Frequency k_Three(Step S86), the data slot length is increased as shown in FIG. 5A, and communication is started (step S87).
[0104]
  The wireless adapter 4b that has received a call from the wireless adapter 4c also receives the frequency f (step S88; YES).₂(Step S89), respond to the wireless adapter 4c (step S90), switch the hopping table, and change the frequency k_Three(Step S91) and communication is started (step S92).
[0105]
  Where the frequency is k_ThreeThe reason for hopping is that the value of the hopping counter M at this time is 3. By using the value of the common hopping counter M in this way, frequency hopping synchronized with the master unit and other wireless adapters is performed even after the communication between the wireless adapters is completed. Can communicate with.
[0106]
  Also, by increasing the data slot length when performing communication between wireless adapters, the amount of data transmission can be increased and the data rate can be increased.
[0107]
  Further, in communication between wireless adapters, by using a hopping table different from the hopping table used for communication with the master unit, communication between wireless adapters can be reliably performed without interfering with other communication. . Note that the hopping table used for communication between the wireless adapters does not have to be completely independent of the hopping table used for communication with the base unit._n= F_{n + 2}As described above, the hopping table used for communication with the parent device may be shifted in phase. In this case, it is not necessary to hold a plurality of hopping tables, and the correction value 2 need only be added to the value M of the hopping counter by the hopping controller.
[0108]
  Further, since the call and response described above are performed in the call response slot, even if performed at the frequency f1, the frequency is different although the timing overlaps with the voice slot without interfering with communication between the base unit 1 and the wireless adapter 4a. The communication between the master unit 1 and the voice slave unit 3a is not disturbed.
[0109]
  Next, an interruption process when the wireless adapter is communicating with another wireless adapter or the parent device will be described with reference to FIGS.
[0110]
  For example, as shown in FIG. 5B, it is assumed that data is transmitted from the wireless adapter 4a to the base unit 1 from before the frame Fb1 to the frame Fb1, and at the timing of time t9, the frequency f₀(Step S70). Since communication is currently being performed (step S71; YES), it is determined whether or not a predetermined number of frames have been communicated (step S72). If the predetermined number of frames have not been communicated (step S72; NO), the communication is continued (step S73). However, if the predetermined number of frames have been communicated until the frame Fb1 is reached (step S72). YES), after terminating the communication in the frame Fb1, the communication is temporarily interrupted (step S74), and the hopping table used for communication with the parent device is switched (step S75). However, in this case, since the communication with the base unit has already been performed, the table is not substantially switched. Then, it waits for reception (step S76), and responds to any data transmission from the parent device.
[0111]
  Next, the wireless adapter 4b and the wireless adapter 4c receive the frequency k from the frame Fb4 as shown in FIG._ThreeA case will be described in which communication between wireless adapters is started, communication is performed for a predetermined period thereafter, and the predetermined number of frames is reached in a frame Fc1 shown in FIG. That is, the frequency k at the timing of time t10.₀(Step S70; YES), it is determined whether or not a predetermined number of frames have been communicated (step S72), and when a predetermined number of frames have been communicated. (Step S72; YES), the frequency k₀Communication is interrupted (step S74), the hopping table is switched to the table of FIG. 4B used for communication with the parent device, and the frequency is changed to f at time t11.₁Hop (step S75). And although it will be in reception standby (step S76), when there exists transmission from a main | base station like FIG.5 (c), it can respond to this.
[0112]
  As described above, even when data is transmitted from the wireless adapter to the master unit, communication is interrupted every predetermined number of frames so that transmission data from the master unit can be received. Even during communication, communication is interrupted every predetermined number of frames, and a call from the parent device or another wireless adapter is accepted, so that the parent device or other child device does not wait for a long time.
[0113]
  Thereby, for example, since a small amount of data transmission can be completed in the middle of a large amount of data transmission, the data transmission efficiency can be improved as a whole system.
[0114]
  Note that, in such a call waiting state from other wireless adapters and the like, it is conceivable that there are calls from a plurality of wireless adapters and the like, and therefore priority may be provided according to the calls. For example, communication with the parent device or a specific wireless adapter may be performed with priority.
[0115]
  Next, the process of the communication between the voice handsets will be described based on the flowchart of FIG. For example, as shown in FIG. 5D, an example in which a call is made from the voice slave unit 3b to the voice slave unit 3c when the master unit 1 and the voice slave unit 3a are communicating will be described.
[0116]
  First, the voice handset 3b receives the frequency g at the switching timing of the frame Fd2 shown in FIG.₁(Step S31; NO), and when there is no incoming call from another voice handset (step S40; NO), a call is made to the voice handset 3c. (Step S43; YES), the frequency g is determined at the time t12 shown in FIG.₁Thus, a call is made to the voice handset 3c (step S44), and it is determined whether there is a response from the voice handset 3c (step S45). As a result, when there is no response (step S45; NO), it shifts to the handset call mode (step S46), and continues the call at the above timing until there is a response (steps S31 to S32; NO to S43). YES to step S44).
[0117]
  On the other hand, when there is a response from the voice slave unit 3c as shown in FIG. 5D (step S45; YES), the process proceeds to a hop between slave units (step S47). This hop uses the table shown in FIG. 4D, and uses a frequency different from the frequency used for communication between the parent device and the child device.
[0118]
  The frequency is h at the switching timing of the frame Fd3.₂(Step S48), a standby period similar to that at the time of communication with the parent device is provided (step S49), and the frequency h from the timing of time t13 shown in FIG.₂Thus, communication with the voice slave device 3c is started (step S50). Thereafter, communication is performed in accordance with this sequence until the communication is completed (step S51; NO). When the communication is completed (step S51; YES), the hop between the parent device and the child device is performed again (step S52).
[0119]
  As described above, since the call between the slave units is performed at the position of the sleep slot, communication between the master unit and other slave units is not disturbed, and the slave unit is not intervened via the master unit. Communication is possible. Furthermore, since the hopping table for communication between the slave units uses a hopping table that is completely independent from the hopping table for communication between the master unit and the slave units, it does not interfere with communication between the master unit and the slave units. Communication between slave units is possible. The hopping table used for communication between the slave units is h._k= G_{k + 2}As described above, the hopping table for communication between the parent device and the child device may be shifted in phase. In this case, since it is not necessary to hold a plurality of hopping tables, the controller 60 only needs to add the correction value 2 to the value M of the hopping counter 61.
[0120]
  As described above, according to the present embodiment, communication is performed by providing a data slot and a voice slot in one frame, so that voice data and non-voice data can be efficiently transmitted and received simultaneously.
[0121]
  Further, since communication between the voice slave units or between the wireless adapters is possible independently of the master unit, it is possible to dramatically increase the communication capacity of the entire system. In addition, since the timing and frequency of the call and response between the voice slave units or between the wireless adapters are set as described above, communication of other devices is not interrupted or interrupted during the call and response.
[0122]
  In communication between wireless adapters, since the data slot length is increased, the data transmission rate can be increased.
[0123]
  In this embodiment, the data slot length is increased only during communication between wireless adapters. However, the present invention is not limited to this, and as shown in FIG. When communication is not performed, the data slot may be lengthened also in communication between the master unit and the wireless adapter.
[0124]
  In this embodiment, since the frequency of the voice slot for voice data communication is set to a frequency different from the frequency of the data slot and the transmission / reception timing is set behind the data slot, the hop slot of the voice slave is lengthened. Therefore, it is not necessary to use a high-speed PLL local oscillator for a voice slave unit, and an inexpensive PLL local oscillator can be used.
[0125]
  In addition, since different frequencies are used for the data slot and the voice slot, good communication can be performed without interfering with each other.
[0126]
  The hopping pattern of the non-voice data slave unit may be configured with a frequency with less interference according to the communication status at that time. At this time, the hopping pattern for the voice slave unit may be composed of the remaining frequencies other than the frequency used for the non-voice data slave unit. This is because an audio slot used for audio data communication is shorter than the data slot, and even if one frequency is disturbed, there is no problem in hearing. On the other hand, the reliability of data transmission can be improved by performing packet communication at a frequency with less interference.
[0127]
  In this embodiment, the case where the transmission slot and the reception slot in the voice slot are one set has been described. However, the present invention is not limited to this, and a plurality of sets of transmission slots and reception slots are provided. May be. If comprised in this way, communication between several audio | voice subunit | mobile_units will also be attained. Further, in this case, it is only necessary to use a pair of transmission / reception slots at the end of the frame, and change an unused voice slot to a data slot.
[0128]
【The invention's effect】
  According to the communication device according to claim 1, in the master unit, one frame is divided into a transmission / reception standby period and a transmission / reception execution period in which transmission / reception with the non-speech data slave unit is performed. In the transmission / reception execution period and performs transmission / reception in the slave unit at the same frequency as the frequency corresponding to the transmission / reception execution period, and for other non-voice data in the period after the transmission / reception execution period A call response period between the slave units is provided, a non-voice slave unit transmission / reception execution period synchronized between the non-speech data slave units is provided, and a frequency different from the frequency used for communication with the master unit is set. Communicate between audio data slave unitsOn the other hand, the transmission / reception timing control means of the non-audio data slave unit adopts a configuration in which the length of the transmission / reception execution period is variable according to a request from the master unit.Therefore, the call and response between the non-voice data slave units can be performed without interfering with communication between another non-voice data slave unit and the master unit, and without passing through the master unit. Can be done with each other. Furthermore, since communication between the non-voice data slave units can be performed independently of the master unit, the communication capacity of the entire system can be dramatically increased.Further, since the length of the transmission / reception execution period is made variable according to the request from the master unit, the transmission rate of non-voice data can be improved according to the situation, or the non-voice data transmission / reception processing and calling It is possible to efficiently perform other processing such as response processing.
[0129]
  According to the communication device of claim 2, when performing communication with the voice data slave unit, one frame is added to the voice slave unit transmission / reception standby period in addition to the transmission / reception standby period and the transmission / reception execution period. The transmission / reception execution period for the voice slave unit is divided into the transmission / reception execution period and the transmission / reception execution period for the voice slave unit. Communication between the communication device and the audio data slave device can be performed efficiently without causing mutual interference. Further, it is possible to prevent interfering with communication between the master unit and the voice data slave unit and between the voice data slave units due to communication between the non-voice data slave units. Interference between the communication between the parent device and the non-voice data slave device and the communication between the non-voice data slave devices due to the communication between each other can be prevented. Further, since the call and response between the non-voice data slave units are also performed at a different frequency and at a different timing from the frequency used for communication of the voice data slave units, Interference with the calling and response of the non-voice data slave unit can be prevented.
[0130]
  According to the communication device of claim 3, the call and response between the non-voice data slave unit and another non-voice data slave unit are performed at the same frequency as the frequency in the transmission / reception execution period. Therefore, the frequency hopping synchronization with other devices can be maintained even after the call and response processing without performing complicated hopping data control, and a good communication environment can be provided.
[0131]
[0132]
  Claim4Since the transmission / reception execution period in the non-voice data slave unit is longer than the call response period, data can be transmitted / received at a high data transmission rate.
[0133]
  Claim5According to the communication device described in the above, when the communication between the non-voice data slave units is performed for a predetermined number of frames, a transmission / reception execution period synchronized with the transmission / reception execution period of the master unit is thereafter provided. Communication between specific non-voice data slave units is not continued for a long period of time, and communication with other devices can be performed efficiently.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a schematic configuration of a communication apparatus according to an embodiment of the present invention.
2 is a block diagram illustrating a schematic configuration of a wireless communication unit in the communication apparatus of FIG. 1;
3 is a block diagram showing a frame structure used in the communication apparatus of FIG. 1. FIG.
4 is a diagram illustrating an example of a hop table in the wireless communication unit in FIG. 2;
FIG. 5 is a timing chart showing communication processing in the communication apparatus of FIG. 1;
6 is a flowchart showing communication processing of a master unit in the communication apparatus of FIG.
7 is a flowchart showing communication processing of a voice slave in the communication apparatus of FIG.
8 is a flowchart showing communication processing of the wireless adapter in the communication apparatus of FIG.
FIG. 9 is a block diagram showing a schematic configuration of a transmission / reception apparatus using a conventional frequency hopping method.
[Explanation of symbols]
  1 ... Master unit
  3a-3c ... Voice terminal slave unit
  4a-4c ... Wireless adapter
  6a-6c data terminal
  8,9 ... External line
  11 ... Wireless communication unit
  12. Image output unit
  13. Image reading unit
  14 ... Voice converter
  15 ... Data converter
  32a to 32c ... Wireless communication unit
  33a to 33c ... voice conversion unit
  42a to 42c ... wireless communication unit
  43a to 43c ... Data conversion unit
  59 ... Hopping table
  60 ... Controller
  61 ... Hopping counter
  62: Frame counter
  70: First hop slot
  71: Data slot
  72 ... Second hop slot
  75 ... Voice slot
  80 ... Hop slot
  85 ... Voice slot
  90 ... Hop slot
  91: Data slot
  92 ... Call answering slot

Claims (5)

Frame switching means for switching a frame which is a unit of communication, frequency selecting means for selecting a frequency corresponding to the switched frame, a transmission / reception standby period for stabilizing the frequency in one frame, and a transmission / reception execution period for data transmission / reception A transmission / reception timing control means for controlling transmission / reception timing and a wireless transmission / reception means for transmitting / receiving data at the transmission / reception timing at the selected frequency, at least each of the master unit and the non-voice data slave unit A frequency hopping communication device provided for
The master unit includes, as the frequency selection unit, a unit that selects a frequency corresponding to the transmission / reception execution period in a predetermined order every time the frame is switched.
The non-speech data slave unit provides a transmission / reception execution period synchronized with the transmission / reception execution period of the parent unit as the transmission / reception timing control means, and in the period after the transmission / reception execution period in one frame, When a call response period is established with a non-voice data slave unit and communication is performed with other non-voice data slave units, the non-speech data slave units are synchronized with each other in the frame. A means for providing a transmission / reception execution period for a voice handset;
Further, as the frequency selection means, in the transmission / reception execution period synchronized with the transmission / reception execution period of the parent device, the same frequency as the frequency corresponding to the transmission / reception execution period of the parent device is selected in the same order, when communicating with the non-voice data for the child machine, at the non Onseiko machine transmission and reception periods, Ru comprising means for selecting a frequency different from the frequency used for communication between the master unit and the slave unit With
The communication apparatus , wherein the transmission / reception timing control means of the non-voice data slave unit varies the length of the transmission / reception execution period in response to a request from the master unit. Frame switching means for switching a frame which is a unit of communication, frequency selecting means for selecting a frequency corresponding to the switched frame, a transmission / reception standby period for stabilizing the frequency in one frame, and a transmission / reception execution period for data transmission / reception A voice data slave unit further comprising: a transmission / reception timing control means for controlling transmission / reception timing so as to divide into: and a wireless transmission / reception means for transmitting / receiving data at the transmission / reception timing at the selected frequency.
When the master unit performs communication with the voice data slave unit as the transmission / reception timing control means, in addition to the transmission / reception standby period and the transmission / reception execution period, the master unit transmission / reception standby period, Means for dividing the one frame into a machine transmission / reception execution period;
Furthermore, as the frequency selection means, when the transmission / reception standby period for the voice slave unit is provided, the frequency selection means comprises means for selecting a frequency different from the frequency at the time of the frame switching in a predetermined order,
The voice data slave unit includes, as the transmission / reception timing control unit, means for controlling a transmission / reception execution period in the slave unit in synchronization with the voice slave unit transmission / reception execution period,
Furthermore, as the frequency selection means, comprising means for selecting the same frequency as the frequency corresponding to the transmission / reception execution period for the voice handset in the same order,
The communication apparatus according to claim 1.   The frequency selection means of the non-voice data slave unit sets the frequency in the call response period to the other non-voice data slave unit to the same frequency as the frequency in the transmission / reception execution period. The communication apparatus according to claim 1 or 2. The transmission / reception timing control means of the non-voice data slave unit makes the transmission / reception execution period longer than a call response period with the other non-voice data slave unit. Item 4. The communication device according to any one of Items 3 to 3 . The transmission / reception timing control means of the non-voice data slave unit has a transmission / reception execution period synchronized with the transmission / reception execution period of the master unit in the frame after communication between the non-voice data slave units of a predetermined number of frames. communication device according to any one of claims 1 to 4, characterized in that provision.

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