JPS6278925A - Data communication system - Google Patents

Abstract

PURPOSE:To reduce the influence of the rising time of a synthesizer upon the quantity of data processing per time slot and to improve the throughput by considering a switching transition time precedently to a time slot with which a station can transmit data when a reception frequency is switched to a transmission frequency. CONSTITUTION:Data generated by a data input part 11 such as keys and a sensor is passed through a control part 13. The control part 13 has a time slot based upon a system synchronizing signal provided at the tail of data transmitted previously from a center station X and the reception frequency is switched to the transmission frequency a frequency switching transition time before a time slot with the data is transmitted to control a synthesizer part 15 and a transmission part 14; and a carrier modulated with the data is transmitted from the transmission part 14 through an antenna switching part 17 and an antenna 18. The received data, on the other hand, is passed through the antenna 18 and switching part 17, demodulated 16, and passed to the control part 13. This received data is converted by the control part 13 and outputted to the data output part 12 composed of a printer, a display device.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to a data communication system for wireless transmission.

In particular, the present invention relates to a wireless simplex data communication system between a fixed station and a mobile object such as a vehicle-mounted or portable type.

〔overview〕

The present invention provides a data communication system in which transmission is performed over the same simplex wireless line between a terminal station and a central station, which are equipped with a wireless unit that uses a single synthesizer to switch between a transmitting frequency and a receiving frequency. By taking into account the frequency switching transition time of the synthesizer and switching the synthesizer from the receiving frequency to the transmitting frequency before the time slot in which the own station can transmit data, the rise time of the synthesizer can be reduced relative to the amount of data processed per time slot. This is designed to reduce the impact and increase throughput.

[Conventional technology]

Conventionally, a terminal station and a fixed station each have a radio section that uses one synthesizer to switch between the transmitting frequency and the receiving frequency.In data communication systems that perform simplex wireless transmission, the frequency of the synthesizer is changed within a time slot. I was making a switch.

[Problem that the invention seeks to solve]

However, in such conventional data communication systems, the frequency of the synthesizer is switched within the time slot, so the time length per time slot becomes longer by the frequency switching transition time of the synthesizer, which lowers the throughput of the entire device. There were drawbacks.

The present invention solves the above-mentioned drawbacks, and aims to provide a data communication system that reduces the influence of synthesizer frequency switching on the amount of data processed per time slot and increases throughput.

[Means for solving problems]

The present invention comprises a central station, and a plurality of terminal stations that are connected to the central station via a simplex wireless line and perform data communication with the central station in a time-sharing manner, and the central station and the In a data communication system that includes a synthesizer that generates a signal by switching a receiving frequency and a transmitting frequency, and a control section that controls switching of this synthesizer, the plurality of terminal stations is configured to respond to a request for switching to transmission. The present invention is characterized in that it includes means for applying a control signal for switching from the receiving frequency to the transmitting frequency at a timing that allows for the frequency switching transition time of the synthesizer before a time slot in which the own station can transmit data.

[For production]

When switching from the receive frequency to the transmit frequency with the synthesizer, the control unit takes into account the frequency switching transition time before the time slot in which the own station can transmit data, thereby reducing the rise time of the synthesizer relative to the amount of data processed per time slot. It is possible to increase throughput by reducing the influence of

〔Example〕

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram of a terminal station of a data communication device according to an embodiment of the present invention. The radio portion of the central office is similarly configured. FIG. 2 is a block diagram of a data communication device according to the present invention.

In FIG. 2, a central station X performs half-duplex data communication with vehicle-mounted terminal stations A and C and a portable terminal station B via a wireless link. In FIG. 1, data generated from a data input unit 1) such as a key, sensor, etc. is connected to a transmission data input of a control unit 13.

Here, the feature of the present invention is the frequency switching portion surrounded by a dashed line. That is, the control section 13 has a time slot based on the system synchronization signal provided at the end of the data transmitted from the central station X earlier. The data converted from the control section 13 is connected to the input of the transmitting section 14, and the control signal is connected to the control input of the synthesizer section 15. In the synthesizer section 15, the receiving frequency is switched to the transmitting frequency ahead of the time slot in which data can be transmitted by the control signal by the amount that takes into account the frequency switching transition time, and the transmitting frequency is changed to the transmitting frequency.
connected to. A carrier wave modulated with transmission data is transmitted from the transmitter 14 via the antenna switching section 17 and the antenna 18 to the central station X using its own time slot. When the transmission is completed, the frequency for transmission is switched to the frequency for reception in the synthesizer section 5 under the control of the control section 13, and the frequency is connected to the reception section 16.

On the other hand, data transmitted from the central station X using its own time slot is connected to the receiving section 16 via the antenna 18 and the antenna switching section 17 and is demodulated.

The data demodulated from the receiving section 16 is connected to the received data input of the control section 13. The data converted from the control section 13 is connected to the data output section 12 such as a printer or a display.

The operation of the data communication device having such a configuration will be explained. Data generated by a data input unit 1) such as a key or sensor is passed to a control unit 13. The control section 13 controls the synthesizer section 15 and the transmitting section 14 at timings described later, and the transmitting section 14 outputs a radio carrier wave modulated with data, which is transmitted via the antenna switching section 17 and the antenna 18.

On the other hand, the received data is input to the receiving section 16 through the antenna 18 and the antenna switching section 17, where it is demodulated and passed to the control section 13. This received data is converted by the control section 13 and outputted to the data output section 2, which includes a printer, a display, and the like.

FIG. 3 is a time chart of data transmission from the terminal station of the data communication device of the present invention. Terminal stations A, B, and C transmit data in synchronization with time slot S, and in this example, data is transmitted in time slot St. At this time, the output 01 of the synthesizer section 15 is received at the reception frequency R by the rise time L4 of the synthesizer section 15 from the beginning of the time slot S2.
The transmission frequency is switched from X to transmit frequency TX. Next, at the timing of time slot St, the transmission output 02 modulated by the data output 03 is transmitted. When the data output 03 and the transmission output 0□ are finished being transmitted within the time slot, the output O7 of the synthesizer section 15 is returned to the reception frequency.

FIG. 4 shows the transmission data format of the terminal station of the data communication device of the present invention. Bit synchronization SYN+ is a preliminary signal for stabilizing the system, and frame synchronization 5YN2 is a flag indicating that data will follow. Data D consists of address AD of the own station, command CO to central station X, information 1N, etc.

FIG. 5 shows the transmission data format of the central office of the data communication device of the present invention. Bit synchronization 5YN3 and frame synchronization SYN are bit synchronization SYN shown in FIG.

and frame sync SYN! is the same as Data DA
is a response to the first terminal station A from a plurality of terminal stations transmitted in a slot group to be described later, and consists of an address AD to the other terminal station, commands CO such as ACK and NAK, information IN for the terminal station A, and the like. Data D3
is the response to the next terminal station B. These data DA%D8 continue for the number of terminal stations that have been transmitted, and finally, system synchronization S'/N is provided. System synchronization 5YN5 is for synchronizing time slots.

FIG. 6 is a time chart of transmission data of the data communication device of the present invention. The central station X switches the synthesizer section 15 to the transmission frequency TX prior to transmitting data. After the rise time t of the synthesizer section 15 has elapsed, the transmission data D is transmitted. This is what was explained in FIG. At this time, transmission data D.

It is assumed that the central station X and the terminal stations A, B, and C internally have time slots s, . Time t3 is system synchronization S Y N
, the detection delay time, time t4 is the rise time of the synthesizer, and time t4 is the time slot length. It is assumed that terminal stations A, B, and C arbitrarily select these time slots 81 to S6 to transmit transmission data D.

An example will be explained in which a need arises for terminal station B to transmit data. In order to transmit data in the nearest time slot S2, the terminal station B switches the synthesizer section 15 to the transmission frequency TX in advance by time t4 before the time slot S2 to stabilize the transmission frequency TX, and then performs data transmission within the time slot S2. Transmit the transmission data D3. When the data transmission is completed, the synthesizer section 15 is set to receive frequency R.
Return to X. When the time slot S ends, the central station
X and transmits the transmission data D.

In this case, the terminal station A transmits data D.

Contains responses to B and C.

〔Effect of the invention〕

As explained above, the present invention makes it possible to reduce the influence of the rise time of the synthesizer on the amount of data processing per time slot by switching the synthesizer to the transmission frequency in advance before the time slot in which data is transmitted. It has an excellent effect of increasing throughput.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a terminal station of a data communication device according to an embodiment of the present invention. FIG. 2 is a configuration diagram of a data communication device according to the present invention. FIG. 3 shows data transmission (
Word time chart. FIG. 4 shows the transmission data format of the terminal station of the data communication device of the present invention. FIG. 5 shows the transmission data format of the central office of the data communication device of the present invention. FIG. 6 is a time chart of data transmission by the data communication device of the present invention. 1)...Data input section, 12...Data output section, 1
3... Control section, 14... Transmission section, 15... Synthesizer section, 16... Receiving section, 17... Antenna switching section, 18... Antenna, A, B, C... Terminal station, AD/
...Address, CO...Command, D...Transmission data, IN...Information, L...Wireless line, Ol...Synthesizer section output, 02...Transmission output, 03...
Data output, RX...Synthesizer reception frequency, 5
x-3h...Time slot, SYN,...Bit synchronization, 5YN2...Frame synchronization, 5YN3...System synchronization, t, ~t6...Time, X...Central station. Embodiment terminal station overall diagram, 1 Figure Embodiment device configuration port yfS2

Claims (1)

[Claims] (1) A central station, and a plurality of terminal stations that are connected to this central station via a simplex wireless line and perform data communication with this central station on a time-sharing basis; In a data communication system that includes a synthesizer that generates a signal by switching a receiving frequency and a transmitting frequency, and a control section that controls switching of this synthesizer, the terminal station has a data communication system in which the control section responds to a request for switching to transmission. , a data communication system characterized by comprising means for providing a control signal for switching from a receiving frequency to a transmitting frequency at a timing that anticipates the frequency switching transition time of the synthesizer before a time slot in which the own station can transmit data. .