JPH02116236A - Time division multiplex transmitting system - Google Patents

Abstract

PURPOSE:To control plural terminal units in a short time by forming a group including plural terminal units and providing a simultaneous control mode signal at a transmitting signal to send from a central processing unit to a terminal unit. CONSTITUTION:A group including plural terminal units is formed and a mode signal to be able to designate a simultaneous control mode to control simultaneously all terminal units in one group to a transmitting signal to send from a central processing unit to a terminal unit is provided. Namely, an address signal AD is expressed by, for example, the binary number of 8 bits, when a mode signal MD designates a simultaneous control mode, the high order 4 bits of the address signal AD become an individual address and the low order 4 bits become a group address. At this time, a terminal unit 2 having the same group address is considered to be one group and simultaneously controlled by a control signal CT included in one transmitting signal TR. Thus, the time necessary to operate plural terminal units can be shortened.

Description

Detailed Description of the Invention [Industrial Field of Application] The present invention provides a method for determining the address of a terminal in a network in which terminals and a central processing unit, each of which has an individually set address, are connected via a signal transmission medium. The present invention relates to a time division multiplex transmission system that transmits a transmission signal including an address signal that specifies a terminal, and a control signal that controls a terminal.

[Prior Art] In the conventional time division multiplex transmission system, a transmission signal including an address signal is sent from a central processing unit to a terminal device to which an address has been individually set, and the address specified by the address signal is matches the address of the terminal,
The terminal device performs operations in response to control signals included in the transmission signal.

[Problems to be Solved by the Invention] According to the above conventional configuration, only one terminal can be operated with one transmission signal, so the time required to operate multiple terminals is shortened. The time to transmit the transmission signal multiplied by the number of terminals to operate is equal to the total time, and as the number of terminals to operate increases, it takes a considerable amount of time to operate all the desired terminals. There was a problem that it took a while.

The present invention aims to solve the above-mentioned problems by making it possible to operate multiple terminals at the same time even with a single transmission signal, thereby reducing the time required to operate multiple terminals. The aim is to provide a time-division multiplexing transmission system.

[Means for Solving the Problems] In the present invention, in order to achieve the above object, a group including a plurality of terminals is formed, and a transmission signal sent from the central processing unit to the terminals is assigned to one group. A mode signal is provided that allows you to specify a simultaneous control mode that simultaneously controls all terminals within the network.

As a method of grouping, there is a method of grouping terminals having a specific part of the address in common.

Alternatively, the address may be expressed numerically, and all terminals having addresses less than or equal to the address value specified by the central processing unit may be grouped. Alternatively, all terminals having addresses greater than or equal to the address value specified by the central processing unit may be grouped into one group.

Furthermore, all terminals having addresses that are greater than or equal to the lower limit and less than or equal to the upper limit specified by the central processing unit may be grouped into one group.

In addition, there are two types: a state in which terminals having a specific part of the address in common are grouped together, and a state in which all terminals having addresses less than or equal to an address value specified by the central processing unit are grouped into one group. All terminals with addresses greater than or equal to the address value specified by the central processing unit are grouped into one group, and all terminals with addresses greater than or equal to the lower limit value and less than the upper limit value specified by the central processing unit are grouped into one group. A group designation signal for selecting one of the states may be included in the transmission signal sent from the central processing unit to the terminal.

[Operation] According to the above configuration, multiple terminals are treated as one group, and the terminals in the group can be controlled simultaneously, so it is easy to control multiple terminals in sequence. Compared to conventional methods, it is possible to control multiple terminals in a short time.

In addition, by providing a group designation signal for selecting the grouping method, it is possible to change the terminals that make up the group. This makes it possible to control the

[Embodiment] As shown in FIG. 1, a central processing unit 1 and a plurality of terminals 2 are connected via signal lines 3 to construct a network system. Each terminal 2 has an individual address, and the central processing unit 1 controls a specific terminal 2 by specifying the address of the terminal 2. As shown in FIG. 2, the transmission signal TR sent from the central processing unit 1 to the terminal device 2 includes a synchronization signal SN,
It includes a mode signal MD, an address signal AD, a control signal CT, and an error detection signal ER. The synchronization signal SN is a signal for synchronizing the timing when the terminal device 2 receives the transmission signal TR from the central processing unit 1. The mode signal MD defines how the meaning of each subsequent signal is to be interpreted. The address signal AD is a signal that specifies the address of the terminal, and the terminal 2 having an address that matches the address specified by the address signal AD,
It performs a predetermined operation in response to the control signal CT. Control signal C
T specifies on/off and setting values for the terminal 2. For example, if a lighting load is connected to the terminal 2, the control signal CT specifies the lighting load. You can turn it on/off and specify the amount of light control. The error detection signal ER is an error detection signal such as a checksum or CRC, and by checking the error detection signal ER, it can be confirmed whether the transmission signal TR has been transmitted correctly.

By the way, the address signal AD is expressed as a binary number of 8 bits I, for example, and when the mode signal MD specifies the simultaneous control mode, the upper 4 bits of the address signal AD are expressed as an individual address, and the lower 4 bits are expressed as an individual address. becomes the group address. At this time, the terminals 2 having the same group address are considered to belong to one group and are simultaneously controlled by the control signal CT included in one transmission signal TR. For example, there are four terminals 2, and the address of each terminal 2 is ■r11010000.
．． , ■r11010001J, ■r11000000J
,■rllo10010. If this is the case, each of the terminals 2 in Binary numbers are written with the left and right sides reversed, with the left end being the least significant bit and the right end being the most significant bit), - the lower order of the address signal AD in the transmission signal TR that includes the mode signal MD of the simultaneous control mode. If the 4 bits are rllol, they are simultaneously controlled by the control signal C'F in the transmission signal TR. Terminal 2 (2) has a different group address, so it is not controlled by the control signal CT.

According to the above configuration, for example, if a lighting load is connected to the terminal device 2, the lights on one floor can be turned on and off all at once. Furthermore, if the fire shutters are connected as a load, the fire shutters in one area can be closed all at once. In other words, since the terminals 2 belonging to the same group receive the control signal CT at the same time, all the target terminals 2 can simultaneously perform a predetermined operation by sending out one transmission signal TR from the central processing unit 1. become,
A plurality of terminals 2 can be operated in a short time.

In the embodiment described above, the lower 4 bits of the address signal AD are used as the group address, but it goes without saying that the upper 4 bits may also be used as the group address. In addition, if a return signal from the terminal 2 is required, a predetermined return period is set after transmitting the transmission signal TR in the simultaneous control mode, and the return signal including the address signal is sent back from each terminal 2 in sequence. or a predetermined return period is provided after the transmission signal TR in the normal operation mode, and - after the transmission signal TR in the simultaneous control mode, the transmission signal TR in the normal operation mode is sequentially sent to each terminal 2. By doing so, the return signal from the terminal 2 may be received.

[Example 2] In the above example, the address is expressed as an 8-bit binary number, and the terminals 2 that share the lower 4 bits are considered as one group. However, in this example, the central processing unit 1 is designated as one group. Terminals 2 having addresses less than or equal to the address value are considered as one group.

In other words, there are four terminals 2, each with ■ "100"
,■"52",■r200. ,■ Assuming that the central processing unit 1 has the address "5" and the central processing unit 1 sends the mode signal MD of the simultaneous control mode and specifies the address as r128°, then the terminal 2 having the address r12B and the following That is, the terminals 2 of ■■■ are controlled simultaneously. Terminal 2 of (2) has an address r128. Since it is larger than , it is not subject to -valve control.

[Third Embodiment] In this embodiment, contrary to the second embodiment, terminals 2 having addresses greater than or equal to the address value specified by the central processing unit 1 are regarded as a group.

In other words, there are four terminals 2, each with ■ "150"
, ■ r200J, ■ rlooo, , ■ r168J, the central processing unit 1 sends the mode signal MD of the simultaneous control mode, and changes the address to "128
, 112B, the terminals 2 having the following addresses, that is, the terminals 2 of ■■■ are controlled at the same time. ■Terminal 2 has address r1
28. Since it is smaller than , it is not subject to -valve control.

[Example 71. ] In this embodiment, the central processing unit 1 specifies two limit values and a lower limit value, and terminals 2 having addresses that are equal to or greater than the lower limit value and have an upper limit value are regarded as a group. In this case, as a matter of course, if the address is expressed as an 8-bit binary number, the address signal AD needs 16 bits 1 to 1.

The upper limit value and lower limit value of the designated address correspond to the upper 8 bits and lower 8 bits 1 of the address signal AD, respectively, as shown in FIG.

In other words, there are four terminals 2, each with ■ "90",
■r 11.2 J, ■r200J, ■r173. The central processing unit 1 sends the mode signal MD for the simultaneous control mode, and sets the lower limit value of the address to "89", and the lower limit value to r196. If this is specified, the terminals 2 having addresses between "89" and r196J, that is, the terminals 2 of ■■■ will be controlled at the same time. Since the address of the terminal device 2 (3) exceeds the upper limit of the specified address, it is not subject to -valve control.

[Embodiment 5] In this embodiment, a group designation signal GR is provided between the mode signal MD and the address signal AD, as shown in FIG. The group designation signal GR selects which of the first to fourth embodiments is used for grouping. In other words, there are two methods: grouping terminals 2 that have the same lower 4 bits of the address, grouping terminals 2 having addresses greater than or equal to a specified address value, and grouping terminals 2 having addresses less than or equal to a specified address value. The user selects which method to group, or to group terminals 2 having addresses between the specified upper limit and lower limit. In this way, by using the group designation signal GR, it becomes possible to change the terminals 2 forming a group depending on the purpose.

” - In the embodiment described above, the signal line 3 was used as the signal transmission medium, but the signal transmission medium is not limited to wired.
Wireless such as light, radio waves, and ultrasonic waves can also be used.

[Effects of the Invention] As described above, the present invention forms a group including a plurality of terminals, and transmits a transmission signal from the central processing unit to the terminals simultaneously to all the terminals in one group. It is equipped with a mode signal that allows you to specify the simultaneous control mode to be controlled. Multiple terminals are treated as one group, and terminals within the group can be controlled simultaneously, so multiple terminals can be controlled in sequence. This method has the advantage that it is possible to control multiple terminals in a short time compared to the conventional method, which had no choice but to control multiple terminals.

Furthermore, if the group designation signal for selecting the grouping method is included in the transmission signal sent from the central processing unit to the terminals, it is possible to change the terminals that make up the group. Since the terminal device that is the target of valve control is changed, there is an advantage that control can be performed in various patterns.

[Brief explanation of the drawing]

FIG. 1 is a schematic configuration diagram showing an example of a time division multiplex transmission system according to the present invention, FIG. 2 is an operational explanatory diagram showing the format of a transmission signal in the same system, and FIG. 3 is a fourth embodiment of the present invention. FIG. 4 is an operation explanatory diagram showing the format of a part of the transmission signal in Embodiment 5 of the present invention. 1... Central processing unit, 2... Terminal, 3... Signal line, AD... Address signal, CT... Control signal, Gl
(...Group designation signal, MD...Mode signal, T
R...Transmission signal. Agent Patent Attorney Ishi 1) Choshichi

Claims (6)

[Claims] (1) In a network in which a terminal device and a central processing unit, each of which has an address set individually, are connected via a signal transmission medium, an address signal that specifies the address of the terminal device and control that causes the terminal device to perform a predetermined operation In the time-division multiplexing transmission system in which a central processing unit sends out a transmission signal containing a signal, a group including multiple terminals is formed, and the transmission signal sent from the central processing unit to the terminal is one. A time division multiplex transmission system characterized by being provided with a mode signal that can specify a simultaneous control mode in which all terminals in one group are controlled simultaneously. (2) The time division multiplex transmission system according to claim 1, wherein terminals having a specific part of the address in common are grouped into one group. (3) The time division multiplex transmission system according to claim 1, wherein the address is expressed numerically, and all terminals having addresses less than or equal to an address value designated by the central processing unit are grouped into one group. (4) The time division multiplex transmission system according to claim 1, wherein the address is expressed numerically, and all terminals having addresses greater than or equal to an address value designated by the central processing unit are grouped into one group. (5) The time-sharing method according to claim 1, wherein the address is expressed as a numerical value, and all terminals having addresses that are greater than or equal to a lower limit value and less than or equal to an upper limit value specified by the central processing unit are grouped into one group. Multiplex transmission method. (6) The above address is expressed numerically, and terminals that share a specific part of the above address are grouped together, and all terminals that have an address less than or equal to the address value specified by the central processing unit. One group is all terminals that have addresses greater than or equal to the address value specified by the central processing unit, and the other is that the addresses are greater than or equal to the lower limit and less than the upper limit specified by the central processing unit. A group designation signal that selects one of the states in which all terminals with
2. The time division multiplex transmission system according to claim 1, wherein the time division multiplex transmission system is included in a transmission signal sent from the central processing unit to the terminal.