JP4000506B2 - Passive communication device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a passive communication apparatus that performs half-duplex data communication between a plurality of base stations and a plurality of terminal stations.
[0002]
[Prior art]
FIG. 14 shows a configuration diagram of a conventional passive communication apparatus disclosed in, for example, Japanese Patent Application Laid-Open No. 2000-13273.
In the figure, 1 is an attached device connected to the base station 10, 2 is a data processing unit for exchanging data with the attached device 1, and 3 is a radio control unit connected to the data processing unit, and a transmitting unit 4 The transmission data 8 is sent to the reception unit 12 and the reception data 13 is received from the reception unit 12. A transmitter unit 6 supplies a carrier signal 7 to the transmission unit 4 and supplies a carrier signal 11 to the reception unit 12. The transmission unit 4 and the reception unit 12 are connected to the transmission antenna 5 and the reception antenna 14, respectively.
[0003]
15 is a receiving antenna of the terminal station 20 that receives the high-frequency signal 9 from the base station 10,
A receiving unit 29 is connected to the receiving antenna 15 and demodulates received data. The demodulated data 19 is input to the radio control unit 28. Reference numeral 21 denotes a data processing unit connected to the radio control unit 28, which outputs the demodulated data 19 sent via the radio control unit 28 to the attachment device 22 and wirelessly inputs the input data from the attachment device 22. The data is sent to the transmission unit 30 via the control unit 28. The transmission unit 30 modulates transmission data and transmits it as a high frequency signal 27 to the base station 10 via the transmission antenna 26.
[0004]
The operation of the conventional passive communication device configured as described above will be described.
In the base station 10, when data is input from the attached device 1 to the data processing unit 2, the data processing unit 2 sends data to the radio control unit 3, and the radio control unit 3 drives the transmission unit 4 to connect the transmission antenna 5. The transmission data 8 is transmitted to the terminal station 20 via the terminal station 20. At this time, the transmitter 4 generates a high-frequency signal 9 obtained by modulating the carrier signal 7 from the transmitter 6 with the transmission data 8.
[0005]
The terminal station 20 receives the high-frequency signal 9 sent from the base station 10 by the receiving antenna 15 and sends it to the receiving unit 29. The receiving unit 29 demodulates the signal and obtains demodulated data 19. The demodulated data 19 is output from the wireless control unit 28 to the attachment device 22 via the data processing unit 21.
[0006]
When the accessory device 22 transmits, when the transmission data is input to the data processing unit 21, the data processing unit 21 sends the data to the wireless control unit 28. The wireless control unit 28 changes the output impedance of the transmission unit 30 connected to the antenna 26 with the transmission data 23. That is, the transmission unit 30 includes a switching element (not shown) such as an FET whose output impedance changes according to the transmission data 23.
[0007]
Since the transmission antenna 26 receives the high-frequency signal 9 transmitted from the base station 10 as in the case of the reception antenna 15, an impedance mismatch occurs between the transmission antenna 26 and the transmission unit 30 due to a change in output impedance. The high frequency signal 9 is modulated by the transmission data 23 and transmitted to the base station 10 as the high frequency signal 27.
[0008]
The receiving antenna 14 of the base station 10 receives the high frequency signal 27 and sends it to the receiving unit 12. The receiving unit 12 mixes the high frequency signal 27 and the carrier signal 11 from the transmitter unit 6 and demodulates the received data 13. The wireless control unit 3 sends the reception data 13 to the data processing unit 2, and the reception data is sent from the data processing unit 2 to the attached device 1, so that bidirectional communication is performed.
[0009]
A time chart of the above operation is shown in FIG.
Transmission data 8 sent from the radio controller 3 of the base station 10 to the transmitter 4 is modulated into a high frequency signal 9 and transmitted to the terminal station 20. The terminal station 20 receives this as received data 19. After the transmission of the transmission data 8, the base station 10 transmits an unmodulated high frequency signal. While the high frequency signal is being output, the terminal station 20 transmits its own transmission data 23 on the high frequency signal 27 to the base station 10.
[0010]
[Problems to be solved by the invention]
In the conventional passive communication device configured as described above, when there are a plurality of terminal stations, transmission data from each terminal station to the base station collide, and the base station transmits from each terminal station. There is a problem that data cannot be received. If attention is paid to the base stations, there is no means for performing communication between the base stations when there are a plurality of base stations.
[0011]
For example, when a base station and a terminal station exist in the same room, radio waves are diffracted on the wall surface of the room when transmitting from the base station to the terminal station, so that the radio waves arrive at the terminal station from various directions. Depending on the degree of diffraction of radio waves arriving from various directions, the arrival time differs, so the amplitude and phase differ, frequency selective fading occurs, and there is a problem that reception is impossible depending on the location.
[0012]
Further, when there are a plurality of base stations, the terminal station does not have means for selecting a base station, and therefore responds to all base stations. That is, when there are a plurality of sets of base stations and terminal stations, there is a possibility that data is transmitted from the base station to another set of terminal stations. Furthermore, when a plurality of base stations transmit data simultaneously, there is a problem that the terminal station cannot receive data.
[0013]
The present invention has been made to solve the above-described problems, and in passive communication in the case where there are a plurality of base stations and a plurality of terminal stations or a set of base stations and terminal stations, a base station or a base station It is an object of the present invention to provide a passive communication device that enables data communication with a terminal station that is desired to be transmitted from a station or a base station that is desired to be transmitted from a terminal station, and which can be reliably transmitted and received between the base station and the terminal station.
[0014]
[Means for Solving the Problems]
The passive communication device according to claim 1 of the present invention is a communication device that performs half-duplex communication between a base station and a plurality of terminal stations, and the terminal station transmits data transmitted from the base station. In the passive communication device that receives the modulated signal of the above and further modulates the non-modulated signal transmitted from the base station with the transmission data from the terminal station and transmits the data, the address setting for setting the address to each of the plurality of terminal stations Means for transmitting data from the plurality of terminal stations to the base station, with reference to the time when reception of the modulation signal of the data transmitted by the base station is completed, the terminal station set by the address setting means Address and terminal maximum Transmitted by each terminal station at the transmission timing generated by the data transmission time The base station transmits the data to the terminal station and then transmits the unmodulated signal for a time determined by the maximum address setting value of the terminal station and the maximum data transmission time of the terminal station. Is.
[0015]
The passive communication apparatus according to claim 2, wherein the base station modulates one transmission data to be transmitted at a plurality of frequencies, and generates a non-modulated wave to be transmitted at the same plurality of frequencies. A high-frequency signal combining transmission data having the same frequency and an unmodulated wave is transmitted at a plurality of different frequencies.
[0016]
The passive communication device according to claim 3 is provided with means for setting the transmission frequency in the base station and means for setting the reception frequency on the terminal station side, the transmission frequency of the base station and the reception frequency on the terminal station side. Are matched with each other.
[0017]
The passive communication device according to claim 4. In , The base station Means for transmitting the transmission data after amplitude modulation, and means for transmitting the transmission data after phase modulation, Concerned From the base station other When transmitting to the base station, Concerned The transmission modulation scheme is switched between when transmitting from the base station to the terminal station.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration of a passive communication apparatus according to Embodiment 1 of the present invention. In the figure, as an example, a system configuration including one base station and two terminal stations is shown. In the figure, the same or corresponding parts as those in the conventional example are designated by the same reference numerals and description thereof is omitted.
10 is a base station, 40 is a terminal station A, and 50 is a terminal station B. Each of the terminal station A40 and the terminal station B50 has an address setting unit 41, and the address setting unit 41 sets the address of the terminal itself.
The base station 10 passes data from the data processing unit 2 to the radio control unit 3, and transmits a radio wave modulated with transmission data from the transmission unit 4 to the terminal station A 40 and the terminal station B 50 via the transmission antenna 5. FIG. 2 shows the structure of transmission data transmitted from the base station 10 to the terminal station A40 and the terminal station B50.
This transmission data structure is composed of, for example, a header part, a data setting part, and a data part addressed to the terminal station. In the header part, various information necessary for the base station 10 to transmit data is described. Describes whether there is data addressed to the terminal station A40 or data addressed to the terminal station B50 in the subsequent data. The subsequent data addressed to the terminal station is described in a fixed length of, for example, 1 byte in the order of the terminal station A40 and the terminal station B50, for example. When the data setting unit has no data addressed to the terminal station A40, for example, and there is data addressed to the terminal station B50, only the data addressed to the terminal station B50 is described following the data setting unit. Addressed data is not listed. The transmitted radio wave is received by the receiving unit 29 via the receiving antennas 15 of the terminal station A 40 and the terminal station B 50, and the received data is passed to the radio control unit 28. The radio control units 28 of the terminal station A40 and the terminal station B50 simultaneously receive this radio wave.
Moreover, immediately after the transmission of the transmission data is completed, the base station 10 transmits an unmodulated signal to obtain transmission data on the terminal station side. The terminal station A 40 and the terminal station B 50 modulate the unmodulated signal with the respective transmission data 23 and transmit the modulated signal to the base station 10 from the transmission antenna 26 as the high-frequency signal 27 of the modulated wave.
[0020]
Next, the operation of the wireless control unit 28 will be described based on the flowchart of FIG. The radio control unit 28 of each terminal station first receives received data from the receiving unit 29 at Step 1. Then, in Step 2, it is determined whether or not there is data addressed to the own station in the data setting unit of received data. If there is no data addressed to the own station (No), there is no data in the data processing unit 21 in Step 3. To be notified. If there is data addressed to the own station at Step 2 (Yes), the data addressed to the own station for a fixed byte length is received, and the data is transferred to the data processing unit 21 at Step 4. Each terminal station sets the timer which sets the timing which a terminal station starts transmission in Step5 after implementing the process of said Step3,4.
[0021]
Here, the timer set for setting the timing will be described using a communication sequence between the base station 10 and the terminal station A40 and the terminal station B50 in FIG.
When transmission data is transmitted from the base station 10, the terminal station A40 and the terminal station B50 receive simultaneously, and since the base station 10 transmits an unmodulated signal immediately after data transmission, while the unmodulated signal is transmitted In addition, the terminal station A40 and the terminal station B50 modulate the non-modulated signal with the transmission data of the local station and use the timer of each terminal station described below with reference to the time when the transmission data from the base station 10 is received. Transmission to the base station 10 is started at the transmission timing based on the set value.
[0022]
First, it is assumed that the address of the terminal station A40 is set to “1” and the address of the terminal station B50 is set to “2”. As shown in FIG. 4, first, the terminal station A40 with the address “1” starts transmission after a predetermined time T1 has elapsed with reference to the time when reception of transmission data from the base station 10 is completed. The predetermined time T1 is a time for compensating for a time lag between the terminal stations that occurs when each terminal station performs reception processing, for example. Specifically, for example, each terminal station receives a data from the base station and starts transmission, a time lag due to an error of a timer held by each terminal station, or each terminal station, for example, every 1 ms This is a time for absorbing the time lag between the terminal stations that occurs due to a reference time setting lag that occurs when the processing method for monitoring data transmitted from the terminal is taken.
Subsequently, the time when the terminal station B50 of the address “2” completes the reception, the predetermined time T1, the maximum time T2 at which one terminal station transmits data, and the time obtained by adding the T1 time. Transmission is started after elapse of T3 time. The T2 time is fixed.
That is, each terminal station sets the timer at a time of T1 + (T2 + T1) * (self address-1) using the self address as a variable, and uses the time when the transmission data from the base station 10 is received as a reference, Data is transmitted to the base station 10 after the timer set value has elapsed.
In this way, when there are a plurality of terminal stations, if the addresses are set to different addresses, the timing of data transmission from each terminal station to the base station can be accurately shifted.
On the other hand, the base station continues to transmit an unmodulated signal in order for the terminal station to transmit data to the base station, but the time for transmitting the unmodulated signal is determined by T1 + (T2 + T1) * number of terminal stations.
[0023]
Then, in Step 6, it is determined whether or not the timer set value has reached the timer = 0. If the timer is not 0 (No), wait until the timer is 0. If the timer is 0 (Yes), At Step 7, data is transmitted from the transmitting unit 30 of the terminal station to the base station 10 via the transmitting antenna 26.
[0024]
The terminal station address is preferably set to "1" and "2" when there are only two such as the terminal stations A40 and B50. For example, if the setting is made as “3” and “5”, the timer set value for setting the transmission timing of the terminal station described above becomes large, so that the transmission timing from the terminal station to the base station 10 is delayed. Since data cannot be transmitted within the time when the non-modulated signal wave is transmitted, the time during which the base station transmits the non-modulated signal may be set to T1 + (T2 + T1) * maximum address setting value.
[0025]
As described above, in passive communication between a base station and a plurality of terminal stations, an address setting unit is provided on the terminal station side, and the base station transmits data when transmitting data from the plurality of terminal stations to the base station. Each terminal station transmits data to the base station at the transmission timing generated by the terminal station address set by the address setting means and the data transmission time of the terminal station, with the time when reception of the data modulation signal is completed as a reference. As a result, the data transmission timing of each terminal station can be shifted, and transmission data from a plurality of terminal stations to the base station can be reliably transmitted between one base station and a plurality of terminal stations. Communication is possible.
[0026]
Embodiment 2. FIG.
In the first embodiment, a case where data is transmitted at a single frequency with a single data structure from the base station to the terminal station is shown. In this embodiment, in order to prevent communication from being impossible when the level is weakened, one transmission data transmitted from the base station is modulated and transmitted at a plurality of different frequencies, and the data An unmodulated wave is transmitted at a plurality of different frequencies that are the same as the modulated wave.
FIG. 5 is a diagram showing communication at a plurality of different frequencies between a base station and a terminal station, each consisting of one base station and four terminal stations.
One base station transmits to four terminal stations simultaneously with one data structure. As described above, each terminal station starts data transmission to the base station with a certain time delay due to the set value of the timer. At this time, the base station calculates the transmission time of its own transmission data and the return time of each terminal station from the timing of transmitting data to the terminal station, and waits until the time elapses. When the time elapses, the base station transmits the same data again to each terminal station at a frequency (for example, frequency 2) different from the previously transmitted frequency (for example, frequency 1) as shown in FIG. . That is, the communication sequence shown in FIG. 4 is repeated by changing the frequency to be transmitted again. The terminal station has a configuration in which the reception unit 29 does not have a frequency selectivity function, and therefore can receive even a different frequency. Therefore, if the terminal station receives at both frequencies (each terminal station received at the frequency 1 and received at the frequency 2 within a certain period of time), the terminal station transmits again at the frequency 1 and Send the same data.
[0027]
The base station receives data twice at the frequency 1 and frequency 2 from the terminal station. However, depending on the frequency, the state in which the radio wave reaches changes, so that the base station or the base station Even if there is a case where communication from the terminal to the terminal station is not possible, communication can be performed at either frequency, so that data loss or the like can be reduced. If the same data is received at frequency 2 within a certain period of time after the base station or terminal station receives at frequency 1, the data of the base station and terminal station are discarded by discarding the data at frequency 2. Prevents double detection.
[0028]
As described above, since one transmission data and unmodulated wave transmitted from the base station are transmitted at a plurality of different frequencies, when transmitting from the base station to the terminal station, for example, reflection from the wall surface of radio waves Even if communication cannot be performed when the signal level of the radio wave is weakened due to the radio wave that reaches directly, it is possible to communicate at any one of a plurality of different frequencies. Etc. can be prevented.
[0029]
Embodiment 3 FIG.
Assuming that the passive communication device is used in a general home, the radio wave may reach the neighbor due to the characteristics of the radio wave. That is, when a set of a base station and a terminal station is used in, for example, two adjacent homes, a case where the terminal station of the own home reacts to the base station of the neighbor may occur. In order to prevent this, in the present embodiment, the base station is provided with transmission frequency setting means and the terminal station is provided with reception frequency setting means so that the transmission frequency of the base station matches the reception frequency of the terminal station. To communicate.
FIG. 6 shows a configuration diagram in which the frequency setting unit of the terminal station is arranged.
In the figure, the same or corresponding parts as those of the terminal station in the system configuration diagram of FIG. A layout diagram of the frequency setting unit transmitted by the base station is omitted. In FIG. 6, reference numeral 42 denotes a frequency setting unit that sets the frequency received from the base station.
For example, the base station and the terminal station have a plurality of sets such as frequency 1 and frequency 2 described above, and the transmission frequency is set by the transmission frequency setting unit (not shown) of the base station so as not to interfere with the neighbors, By setting the frequency received by the terminal station side by the frequency setting unit 42 shown in FIG. 6 and performing communication so that the transmission frequency of the base station matches the reception frequency of the terminal station side, To prevent the home terminal station from reacting to the base station.
[0030]
As described above, the base station is provided with means for setting the frequency of the radio wave to be transmitted to the terminal station, and the terminal station is provided with means for setting the reception frequency of the radio wave to be transmitted from the base station. By performing communication by matching the reception frequency on the terminal station side, when a base station and a set of terminal stations are installed in, for example, two adjacent ordinary homes, It is possible to prevent the terminal station from reacting.
[0031]
Embodiment 4 FIG.
In the first to third embodiments, the embodiment in the passive communication including one base station and a plurality of terminal stations has been described. However, in the present embodiment, the base station and one or more terminal stations are included. Communication between base stations when there are a plurality of passive communication systems will be described.
FIG. 7 is a diagram illustrating communication between two base stations, for example. In FIG. 7, the same or corresponding parts as those of the base station in the system configuration diagram of FIG. Note that the terminal stations of the base stations 10A and 10B are omitted.
In the figure, 10A and 10B are base stations, each having an address setting unit 60, and the address setting unit 60 sets the address of the own station.
Reference numeral 9 'denotes a communication signal between base stations composed only of a signal obtained by modulating a high frequency signal with transmission data.
When transmitting from one base station to another designated base station, it is necessary to set each base station address. As shown in FIG. By setting different addresses for the stations 10A and 10B, the addresses of the base stations 10A and 10B are determined.
[0032]
In order to receive the transmission data of the terminal station on the base station side, as shown in the communication sequence of FIG. 4, the terminal station transmits the unmodulated signal wave while the base station transmits the unmodulated signal wave. Since the terminal station modulates and returns the data, the terminal station transmits the unmodulated signal wave when the terminal station modulates the data so that the transmission of the unmodulated signal wave of the base station and the data modulated transmission of the terminal station do not collide. It is necessary to modulate to a frequency different from the frequency. Therefore, as shown in FIG. 8, for example, when transmitting data and a non-modulated signal from the base station to the terminal station, transmission is performed at 2400 MHz, and when transmitting data from the terminal station to the base station, transmission is performed at 2400.4 MHz. On the other hand, since the base station is configured to receive the data-modulated radio wave of the terminal station, when transmitting from the base station to another base station, 2400 MHz data transmitted from the base station to the terminal station In transmission, the base station cannot receive. Therefore, when transmitting data from a base station to another base station,
Instead of the frequency of 2400 MHz transmitted from the base station to the terminal station, it is necessary to transmit at a frequency of 2400.4 MHz for data transmission from the terminal station to the base station as shown in FIG.
[0033]
Next, a method for changing the frequency of the unmodulated wave from the terminal station side will be described. As shown in FIG. 10, the phase of data is inverted between “data 1” and “data 0” at a frequency of 400 KHz for a modulated wave that is data-modulated from a terminal station. ”Is the same, for example, 50 μs. This is mixed into an unmodulated signal wave of 2400 MHz, and data is transmitted from the terminal station to the base station. Thereby, it can transmit to a base station from a terminal station with the frequency of 2400.4 MHz mentioned above.
Therefore, when transmitting from the base station to the base station, in the same way as when the terminal station transmits data to the base station, the base station transmitting unit 4 converts the unmodulated wave of 2400 MHz to 400 KHz as shown in FIG. 2400 MHz when mixing the data whose phase is inverted (phase-modulated) with “data 1” and “data 0” at the frequency, and transmitting at 2400.4 MHz and transmitting from the base station to the terminal station As shown in FIG. 11, a state where a modulated wave of “data 1” is 2400 MHz as shown in FIG. 11 is continued for, for example, 50 μs for the same time as the phase inversion of the data, and “data 0” is 2400 MHz. Data (amplitude-modulated) assigned to a state where no modulated wave exists is mixed and transmitted at 2400 MHz.
This makes it possible to implement both transmission from the base station to other base stations and transmission from the base station to the terminal station, and there are a plurality of passive communication systems comprising the base station and one or more terminal stations. In this case, communication between the base stations and communication between the base station and the terminal station can be easily performed.
[0034]
FIG. 12 shows a communication sequence between base stations, that is, between the base station 10A and the base station 10B. As described above, in the communication between the base station and the terminal station, since the base station receives transmission data from the terminal station, it is necessary to transmit an unmodulated signal wave to the terminal station. However, in the communication between base stations, the base station does not need the unmodulated signal wave of the other base station, so the high-frequency signal (unmodulated signal) portion of the communication sequence shown in FIG. 4 is not necessary. The high-frequency signal 9 'in FIG. 12 is transmitted with only a signal modulated by transmission data.
[0035]
As described above, since the transmission modulation method is switched between communication from the base station to another base station and communication from the base station to the terminal station, passive communication including the base station and one or more terminal stations is performed. Even when there are a plurality of systems, communication between base stations and communication between base stations and terminal stations can be facilitated without requiring special means.
[0036]
Note that the frequency of communication between the base station and the terminal station or between the base stations in the above embodiment is merely an example, and is not limited to this.
[0037]
Embodiment 5 FIG.
In the passive communication apparatus, since the terminal station cannot transmit data without transmission of an unmodulated signal wave from the base station, the base station frequently repeats transmission of an unmodulated signal wave to receive data of the terminal station. Therefore, when there are a plurality of passive communication devices consisting of a base station and a terminal station, transmission data of the base station collides due to transmission between the base stations, or transmission data of the terminal station that modulates the unmodulated signal wave of the base station Collisions often occur. In order to prevent this, in this embodiment, before the base station transmits transmission data, the state of the radio wave (carrier) on the antenna is detected, and from the carrier detection state, for example, when the carrier is empty To send.
When transmitting at multiple frequencies as described above, the base station sequentially switches to multiple frequencies for detecting radio waves on the antenna to detect the frequency of multiple radio waves used for communication between the base station and the terminal station. The carrier state on the antenna is detected depending on whether data can be received at each frequency.
[0038]
For this detection, FIG. 13 shows a flowchart in the case of detecting the carrier state by the microprocessor.
For example, when there are two types of frequencies, first, in Step 11, the frequency is set to frequency 1, and in Step 12, an interruption to the port is waited for a certain period of time. If there is an interrupt, the carrier is present, and in step 13, the port data is checked to check whether the carrier is data for the own station. Then, if it is data to the own station, the reception process is performed. If it is not the data for the own station, the process returns to Step 11 to set the frequency 1, waits for the interruption to the port again for a certain time, and waits for the disappearance of the carrier.
If there is no interruption at frequency 1, it means that there is no carrier of frequency 1, and then at step 14, the frequency is set to frequency 2, and at step 15, as in the case of frequency 1, the time is constant. Waiting for an interrupt to the port, if there is an interrupt, a carrier of frequency 2 exists, and at step 13, the port data is checked to check whether the carrier is data addressed to the own station. If it is data to its own station, it performs reception processing. If the data is not addressed to the own station, the process returns to Step 11 to check from the presence of the carrier having the frequency 1. For example, if there is only a carrier of frequency 2 on the antenna, the sequence is repeated until there is no carrier of frequency 2 in Step 15. In this way, if there is no interruption at frequency 1 and frequency 2, it is determined at step 16 that there is no carrier, and data is transmitted from the base station.
[0039]
As described above, since the radio wave (carrier) state on the antenna such as between the base station and the terminal station is detected, since it can be transmitted from the carrier detection state, for example, when the carrier is idle, the base station Communication between base stations and terminal data that modulates non-modulated signal waves of the base station can be prevented, and communication from the base station to the terminal station can be prevented. Errors and communication errors from the terminal station to the base station can be prevented.
[0040]
【The invention's effect】
As described above, the passive communication device according to claim 1 of the present invention is a passive communication device that performs half-duplex communication between a base station and a plurality of terminal stations, and the terminal station is provided with address setting means, When transmitting data from the plurality of terminal stations to the base station, the terminal station address and the terminal station set by the address setting means with reference to the time when reception of the modulation signal of the data transmitted by the base station is completed of maximum Each terminal station transmits data to the base station at the transmission timing generated by the data transmission time. The base station transmits the data to the terminal station and then transmits the unmodulated signal for a time determined by the maximum address setting value of the terminal station and the maximum data transmission time of the terminal station. As a result, the data transmission timing of each terminal station can be shifted, and transmission data from a plurality of terminal stations to the base station can be reliably transferred between one base station and a plurality of terminal stations. A passive communication device capable of performing communication can be obtained.
[0041]
Further, in the passive communication device of claim 2, the base station generates means for modulating one transmission data to be transmitted at a plurality of different frequencies and generates a non-modulated signal wave to be transmitted at the same plurality of different frequencies. Since a high frequency signal combining transmission data having the same frequency and an unmodulated signal wave is transmitted at a plurality of different frequencies, when transmitting from a base station to a terminal station, for example, from the wall surface of radio waves Even if communication is not possible when the signal level of the radio wave is weakened due to the reflected wave and the radio wave that reaches directly, it is possible to communicate at any one of the multiple frequencies, such as data loss Can be prevented.
[0042]
According to another aspect of the present invention, there is provided a passive communication device comprising means for setting transmission frequencies of transmission data and unmodulated signal waves in the base station, and transmission data and radio waves of unmodulated signal waves from the base station on the terminal station side. Since a means for setting the reception frequency is provided, the base station and the terminal station can communicate with each other with the same transmission / reception frequency, so a set of base stations and terminal stations is installed in two adjacent households. In this case, it is possible to prevent the home terminal station from reacting to the neighbor base station.
[0043]
According to a fourth aspect of the present invention, there is provided a passive communication device having means for transmitting the transmission data after amplitude modulation of the transmission data and means for transmitting the transmission data after phase modulation of the transmission data, and the base station transmits to another base station. Since the transmission modulation method is switched between the case of transmitting to the terminal station and the case of transmitting to the terminal station, when there are a plurality of passive communication devices including the base station and the terminal station, no special means is required and And communication between the base station and the terminal station can be easily performed.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of a passive communication device according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram of transmission data transmitted from a base station to a terminal station according to Embodiment 1 of the present invention.
FIG. 3 is a flowchart of data transmission from the terminal station to the base station according to Embodiment 1 of the present invention;
FIG. 4 is a diagram showing a communication sequence between a base station and a terminal station according to Embodiment 1 of the present invention.
FIG. 5 is a diagram illustrating communication at a plurality of different frequencies between a base station and a terminal station according to Embodiment 2 of the present invention.
FIG. 6 is a configuration diagram in which a frequency setting unit of a terminal station according to Embodiment 3 of the present invention is arranged.
FIG. 7 is a diagram showing communication between base stations in Embodiment 4 of the present invention.
FIG. 8 is a diagram showing a communication frequency between a base station and a terminal station according to Embodiment 4 of the present invention.
FIG. 9 is a diagram showing a communication frequency from a base station to another base station according to Embodiment 4 of the present invention.
FIG. 10 is a diagram showing a data transmission waveform when transmitting from a terminal station to a base station according to Embodiment 4 of the present invention;
FIG. 11 is a diagram showing a data transmission waveform when transmitting from a base station to a terminal station according to Embodiment 4 of the present invention;
FIG. 12 is a diagram showing a communication sequence between base stations according to Embodiment 4 of the present invention.
FIG. 13 is a diagram showing a flowchart for detecting a radio wave (carrier) state on an aerial line according to Embodiment 5 of the present invention;
FIG. 14 is a configuration diagram of a conventional passive communication device.
FIG. 15 is a timing chart in communication between a base station and a terminal station of a conventional passive communication device.
[Explanation of symbols]
3 radio control unit, 4 transmission unit, 10, 10A, 10B base station, 12 reception unit, 28 radio control unit, 29 reception unit, 30 transmission unit, 40 terminal station A, 41 address setting unit, 42 frequency setting unit, 50 Terminal station B, 60 Address setting section.

Claims (4)

A communication device that performs half-duplex communication between a base station and a plurality of terminal stations, wherein the terminal station receives a modulation signal of data transmitted from the base station, and is further transmitted from the base station In a passive communication device that transmits data by modulating a non-modulated signal with transmission data from a terminal station ,
An address setting means for setting an address in each of the plurality of terminal stations ;
When transmitting data from the plurality of terminal stations to the base station ,
Based on the time when reception of the modulated signal of the data transmitted by the base station is completed ,
At the transmission timing generated by the address of the terminal station set by the address setting means and the maximum data transmission time of the terminal station, each terminal station transmits ,
The base station
After sending data to the terminal station,
A passive communication apparatus , wherein the unmodulated signal is transmitted for a time determined by a maximum address setting value of the terminal station and a maximum data transmission time of the terminal station .   The base station has means for modulating one transmission data to be transmitted with a plurality of frequencies and means for generating a non-modulated wave to be transmitted with the same plurality of frequencies, and has no transmission data having the same frequency. The passive communication device according to claim 1, wherein a high-frequency signal combining modulated waves is transmitted at a plurality of different frequencies.   A means for setting a transmission frequency in the base station and a means for setting a reception frequency on the terminal station side are provided, respectively, and the transmission frequency of the base station matches the reception frequency on the terminal station side. Item 2. The passive communication device according to Item 1. The base station has means for amplitude-modulating transmission data for transmission, and means for phase-modulating transmission data for transmission,
And when transmitted from the base station to another base station, in the case of transmitting from the base station to the terminal station, one of the claims 1 to 3, characterized in that to switch the modulation method of the transmission A passive communication device according to claim 1.

Images