JPS6123700B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a data transmission device that transmits a plurality of different types of data to respective receiving stations provided corresponding to the data.

Conventionally, there has been a transmission device of this type as shown in FIG. In FIG. 1, 1a to 1n
is a transmitting station, 2x, 2y, and 2z are receiving stations for data X, Y, and Z, respectively, and 3 is a switching network. Also,
Each of the transmitting stations 1a to 1n includes a network control section 11, a modulation section 12, an encoding section 13, a scanning section 14, and a demodulation section 1.
5, decoding section 16 and hybrid coil 17
Each receiving station 2x, 2y, 2z includes a network control section 21, a demodulation section 25, and a decoding section 2.
6, a modulation section 22, an encoding section 23, and a hybrid coil 27.

Next, the operation will be explained. In Figure 1,
The receiving station 2x selectively collects only data of type X out of each data transmitted from each of the transmitting stations 1a to 1n, and similarly, receiving stations 2y and 2z selectively collect data of types Y and Z, respectively. shall be collected. The process by which the receiving station 2x collects data X from the transmitting station 1a is as follows.

An activation (transmission) request to the transmitting station 1a is output from the receiving station 2x to the switching network 3 via the network control unit 21.

The switching network 3 outputs a paging signal to the transmitting station 1a.

This paging signal is input to the network control section 11 of the transmitting station 1a, and this network control section 11 responds.

A transmission path between the transmitting station 1a and the receiving station 2x is formed through the network controllers 21 and 11.

A "data X transmission request code (data type designation code)" is input to the encoding unit 23 of the receiving station 2x, and this is transmitted from the modulation unit 22 as an FS signal.

The demodulating section 15 of the transmitting station 1a demodulates this FS signal and outputs it to the scanning section 14 via the decoding section 16.

The scanning unit 14 inputs only data X to the encoding unit 13, which converts it into a serial pulse train, and this converted data
2, it is modulated into an FS signal and sent to the transmission path.

The demodulator 25 of the receiving station 2x demodulates this FS signal, and the decoder 26 reproduces data X.

Although the receiving station 2x collects type X data from the transmitting station 1a through the above process, it is also possible to collect type X data from the other transmitting stations 1b to 1n through a similar process. Similarly, the receiving stations 2y and 2z can collect data of types Y and Z from each of the transmitting stations 1a to 1n, respectively.

In this way, in the conventional device, each receiving station 2x, 2
y, 2z transmits a "data transmission request code" to the transmitting stations 1a to 1n, and the transmitting stations 1a to 1n receive this and transmit only the data corresponding to the receiving station that has made the data transmission request. Therefore, each receiving station 2x, 2y, 2z has a transmission function for transmitting a "data transmission request code".
In addition, each of the transmitting stations 1a to 1n requires a receiving function for receiving signals, which increases the amount of hardware required for each transmitting and receiving station, which is a major obstacle to reducing power consumption, size, and cost.

This invention was made in order to eliminate the drawbacks of the conventional devices as described above, and its purpose is to provide a data transmission device that can reduce the hardware of transmitting and receiving stations without degrading the data transmission function. There is.

An embodiment of the present invention will be described below with reference to the drawings. In FIG. 2, 1a to 1n are transmitting stations, 2
Reception stations x, 2y, and 2z selectively receive only data X, Y, and Z, respectively, and 3 is a switching network.
Each transmitting station 1a to 1n includes a network control section 11, a modulation section 1
8. Consisting of an encoding unit 19 and a scanning unit 20,
Each receiving station 2x, 2y, 2z includes a network control section 21, a demodulation section 28, and a decoding section 26.

The major difference from FIG. 1 is that the transmitting stations 1a to 1n
In this case, the demodulation section 15, decoding section 16, and hybrid coil 17 for receiving the "data transmission request code" are eliminated, and the coding section 19 and the scanning section 2
Data type switching signal and modulation unit 18 for 0
The point is that the FS signal center frequency switching signal is output to the receiving station 2x, 2y, 2z, the encoding section 23, modulation section 22 and hybrid The point is that the coil 27 is missing.

Next, the operation will be explained. It is assumed that FIG. 2 has the same system conditions as FIG. 1. That is, among the data transmitted from the transmitting stations 1a to 1n, the receiving stations 2x, 2y, and 2z selectively collect only data of types X, Y, and Z, respectively. The process by which the receiving station 2x collects data X from the transmitting station 1a is as follows.

~ The process is the same as that shown in FIG. 1 until a transmission path is formed via the network controllers 21 and 11 in response to an activation request from the receiving station 2x to the transmitting station 1a.

The encoding unit 19 starts operating at the same time as the transmission path between the network control unit 21 of the receiving station 2x and the network control unit 11 of the transmitting station 1a is activated.

At the same time as the start of operation, the encoding unit 19 sends a data type switching signal to the scanning unit 20 to the modulating unit 1.
8, outputs an FS signal center frequency switching signal.

The scanning unit 20 sequentially switches data X, Y, and Z according to the data type switching signal and supplies the data to the encoding unit 19.

In the encoding unit 19, the input data X, Y,
Z is sequentially converted into a series pulse train and supplied to the modulation section 18.

In the modulation section 18, each input data X, Y,
The serial pulse train of Z is modulated into an FS signal, and in this case, the modulation center frequency of each data X, Y, and Z is switched for each data according to the center frequency switching signal from the encoder 19. In other words, data X, Y, and Z have their respective modulation center frequencies.
The FS signals _x , _y , _z are sent out sequentially, and sent to each receiving station 2x, 2y, 2 via the switching network 3.
transmitted to z.

The demodulator 28 of the receiving station 2x uses the demodulation center frequency
The FS demodulator set to _x demodulates only the data X out of the FS signals transmitted via the switching network 3, and supplies the obtained serial pulse train to the decoding section 26. (In addition, other receiving stations 2y, 2
The demodulation center frequencies of the demodulator 28 of z are respectively
It is set to _y , _z . ) The decoding unit 26 reproduces parallel data X from the input serial pulse train.

As described above, the receiving station 2x has collected data of type X from the transmitting station 1a, but it is possible to collect data of type X from the other transmitting stations 1b to 1n in exactly the same manner. Also, by using exactly the same process, the receiving stations 2y and 2z can selectively collect data of types Y and Z from each of the transmitting stations 1a to 1n, respectively.

In the above embodiment, the transmission paths between the transmitting stations 1a to 1n and the receiving stations 2x, 2y, and 2z are configured by the switching network 3 and the network control units 11 and 21, but this is Needless to say, the present invention can be similarly applied to lines and other types of transmission paths. However, in this case, simultaneous activation from a plurality of receiving stations is mutually prohibited due to, for example, time division activation or first-come-first-served activation. In addition, although the above embodiment describes the case of transmission using the FS signal, other signals such as
It can also be transmitted using AM, FM signals, etc.
The same effects as in the above embodiment can be obtained. However, in this case, the transmitting station may sequentially switch the transmitting frequency band, and the receiving station may receive only signals in different receiving frequency bands.

As described above, according to the present invention, the receiving frequency bands of each receiving station corresponding to each data are set to different bands, and the transmitting frequency band of each data is set to the receiving frequency band of each receiving station. In response to a data transmission request from one of the above receiving stations, the transmitting station switches the transmission frequency band set for each piece of data and sequentially transmits each piece of data. This eliminates the need for a transmitting/receiving function for transmitting and receiving "request codes," making it possible to greatly reduce the amount of hardware required for the entire transmission system.This reduction in hardware also makes the transmission system smaller, cheaper, and more reliable. It directly contributes to sexual performance and has a great practical effect.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing a conventional data transmission device, and FIG. 2 is a block diagram showing a data transmission device according to an embodiment of the present invention. In the figure, 1a to 1
n is a transmitting station, 2x, 2y, 2z are receiving stations, 3 is a switching network, 11 is a network control unit, 18 is a modulation unit, 19 is an encoding unit, 20 is a scanning unit, 21 is a network control unit, 26 is a decoding unit 28 is a demodulating section. In the drawings, the same or corresponding parts are designated by the same reference numerals.

Claims (1)

[Claims] In a data transmission device that transmits a plurality of different types of data to receiving stations provided corresponding to each data, different bands are set according to each of the plurality of data to be received. a plurality of receiving stations that receive only signals in respective receiving frequency bands; A data transmission device comprising: a transmitting station that sequentially transmits data in a transmission frequency band equal to the frequency band.