KR100617678B1 - Serial Numbering System and Method for Daisy-Chained Systems - Google Patents

Abstract

Disclosed is a serial numbering system of a daisy chained system. A daisy chained system includes a system ID detector for detecting a system ID, an input connector for receiving an ID related signal, an output connector for outputting an ID related signal to the next subsystem, and a plurality of connections between the input connector and the output connector. It includes multiple systems of ID-related signal lines and cables for daisy chaining these multiple systems.

Description

Serial Numbering System and Methods for Daisy-Chained Systems

The present invention relates to a serial numbering system and method of a daisy-chained system, in particular to each subsystem when the same or similar systems are operated as one large system by daisy chaining. The present invention relates to a system and method for assigning unique serial numbers (unique IDs) to provide information for use in application programs such as diagnostic processing, isolation processing, and configuration management.

In general, when daisy chaining or stacking multiple identical systems to operate as a single system, each system must have a unique number. This number, usually given in the form of a serial number, becomes a unique ID that is used for hardware and software information.

In this case, conventional methods require the use of dip switches or plug jumpers to set individual serial numbers for each system. That is, the output connector 14 of the system # 1 (10) is connected to the input connector 22 of the system # 2 (20) by using the dip switches 16, 26, 36 according to the manual method, and the system # 2 By connecting the output connector 24 of (20) to the input connector 32 of the system # 3 (30) to the n-th system, the serial number of each system is directly assigned.

When a number is assigned by manual method, it is used as its own ID until the number is changed. 1 is a block diagram illustrating a conventional serial number sub-assignment method operated as described above.

Therefore, in the conventional technology as described above, by using a method for setting one by one, when a mistake occurs by manual operation, it is inconvenient to find and reset it. In addition, if you change the order of the chained stacking system or stacking system, there is a problem of reducing the inconvenience and workability to reset again.

Therefore, the present invention was devised to solve the problems as described above, and any system can be easily assigned to its ID by automatically assigning serial numbers according to the old order once a chain is formed or stacked and connected. It is an object of the present invention to provide a serial numbering system and method for daisy chained systems.

Another object of the present invention is to provide a hardware system that automatically assigns serial numbers according to the connection sequence when all the systems are connected, so that the serial number of a daisy chained system can be easily known and managed by a user or a system administrator. It is an object to provide a placement system and method.

It is yet another object of the present invention to provide a serial numbering system and method for daisy chaining systems that improve the quality and service of the system by easily utilizing the automatically assigned serial number as information for supporting software in the internal system. It aims to do it.

The above and other objects and novel features of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.

In order to achieve the above object, a preferred embodiment of a serial number assignment system of a daisy chained system according to the present invention, in a daisy chained system, includes a system ID detector for detecting a system ID and an ID related signal. Daisy chaining a plurality of systems with a plurality of systems comprising an input connector for receiving an input and an output connector for outputting the ID-related signal to the next subsystem, and a plurality of ID-related signal lines connecting between the input connector and the output connector It includes a cable for.

In the present embodiment, it is preferable that the first signal line is connected to a power supply (Vcc) terminal and the last signal line is connected to a ground (GND) terminal.

In addition, in the present embodiment, it is preferable that the plurality of ID-related signal lines should be pre-allocated on the printed circuit board by the total number of systems +1 in order to generate serial numbers of the respective subsystems.

In another embodiment, when the first subsystem of the daisy chained system is built as a master system, the powered-on subsystems receive serial numbers according to the original connection order even when the other subsystems are powered off. It is desirable to be.

In a preferred embodiment of the method for assigning serial numbers of a daisy chained system according to the present invention, a system consisting of daisy chains or stacking several identical systems may be configured as a whole system, and each system power supply in the whole system may be configured. Turning on, connecting an input connector and an output connector on the printed circuit board in each of the powered-on systems, all signals are connected through the cable of the entire system and the input connector and the output connector to connect the input connector of each system. Only one of the pins is made high, setting the value of the pin being high to a register of a system ID detector, and each system recognizing the value of the register as its own ID number.

In the present invention, to reduce the problems and inconveniences appearing in the conventional method, any system once a chain or just stacked and connected, by automatically assigning the serial number according to the order so that it can be easily assigned to their ID I would like to. Here, the serial number is used as some administrative data to be used as diagnostic information, configuration management, or unique information for transmitting a command by protocol to each system.

The system of the present invention corresponds to a daisy chain or stacking system by cabling, and the main block is divided into a system signal configuration through an input connector and a system signal configuration through an output connector. Each system exchanges information through a common bus for interconnecting each other. Assigning a signal line to provide a unique number to this public bus allows it to be entered and used by each system through connected cables and connections.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

If you want to act as a system by stacking multiple daisy chained systems or multiple identical systems, each system must have its own serial number (ID) to differentiate the systems.

Thus, the present invention has a configuration as shown in FIG. 2 for each system to be assigned a unique serial number. 2 is a detailed system diagram and system connection diagram for assigning a serial number of a daisy chained system according to the present invention.

Referring to FIG. 2, each of the systems includes an input connector 120, 220, 320, 420 that receives an ID-related signal, an output connector 130, 230, 330, 430 that outputs an ID-related signal to the next system, and the input. It consists of 3 blocks of the system ID detector that detects the ID of the corresponding system according to the signal received from the connector and stores the detected ID for later use, and the ID related signal line connecting the input connector and the output connector is printed. It should be designed and fixed on the printed circuit board (PCB). Each system is connected via a cable to daisy chain.

In the present invention, the entire system is composed of five ID-related signals, but by adding some signal line assignments according to actual needs, the system can be continuously expanded. That is, in order to generate unique serial numbers of each system, ID related signals of 'total number of systems +1' must be allocated in advance.

The system configured as above operates as follows. 3 is a flow chart according to the present invention.

First, when the system is configured (S1), power on all the systems (On) (S2).

Then, when the input connector and the output connector are connected on the printed circuit board of each system (S3), all signals pass through the cable and the input / output connector of the entire system and only one pin of the input connector of each system is high. To be (S4).

The high pin value is set to the register of the system ID detector (S5), and each system recognizes the value of the register as its own ID number (S6).

Looking in detail with reference to the connection diagram of Figure 2, as follows.

As the signal lines are assigned according to the total number of systems + 1, four systems 100, 200, 300, and 400 are connected in FIG.

First, since the input connector 120 of the system # 1 (100) is the first system, since there is no signal coming in, only the common bus signal and some signal lines necessary for detecting the serial number related to the present invention are connected, and the output connector 130 is to support a bus protocol by connecting a common bus signal to the system # 2 (200). Of course, each system must be configured with the same signal and protocol to support this common bus, so that it can be applied to mass production, and numbers are automatically assigned in the order of connection.

Therefore, in order to support such a function, signals of each system must be designed and fixed on the printed circuit board in the same way. The other common bus signals must also be allocated and fixed together. That is, ① of the input connector 120 is '1' because it is pulled up from the power supply (Vcc) terminal, ② is connected to the input connector 120 of the system # 4 (400) ⑤ through a number of systems It becomes '0' because it falls to ground (GND). The remaining signals ③ ~ ⑤ are also connected to GND ⑤ of the other system by the same method, and are '0', so the actual value of sys_id [4: 1] becomes '1' and the value is sent to the system ID detector 110. Is entered. The system ID detector 110 detects the subsystem ID as '1' and applies it to the actual system.

In the same way, the system # 2 (200) receives a signal of a [5: 1] through the output connector 130 of the system # 1 (100), and the value at this time is '2'. However, although signal ① is pulled up to '1' in its input connector 120, signal a [1] is input to ⑤ of the input connector via ① of the output connector 130 of system # 1 (100). Connected to GND, the value is '0'. The rest of the signal is also connected to GND of another system by the same method and becomes '0' so that sys_id [4: 1] of system # 2 200 becomes '2'. Similarly, a value of '2' is input to the system ID detector. The system ID detector 110 detects the subsystem ID as '1'.

Looking at the system # 3 (300), since it is connected to the ③ of the output connector 230 of the system # 2 (200), it maintains' 1 'and the remaining ①, ②, ④, ⑤ is finally connected to GND,' 0 Has a value.

In this way, all the systems are applied equally, and each system has the sys_id [4: 1] values sequentially according to the connection order, and the values are the system ID detectors 110, 120, 130, and 140. Likewise, the registers can be accessed by the processor.

As a result, each system can automatically receive the serial number by the same system and configuration method, and especially when building system # 1 (100) as the master system, even if the other system is powered off, the live system is still You will receive serial numbers based on the connection sequence, which is very useful for performing applications such as system diagnostics and configuration management.

While the invention is susceptible to various modifications and alternative forms, the disclosure thereof has been described with reference to specific embodiments only. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the specification, but rather that the invention is intended to cover all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to include.

In the present application operating as described above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

The system can be configured during initial system design without the use of dip switches or other additional components for serial numbering.

And since the number setting is done automatically, it is very convenient and does not require any additional work by the user or administrator, and if the connector part for cabling is normal even during reconfiguration or failure of a specific system, the numbering can be assigned without any problem. Can be.

In addition, there is an advantage that it can be very usefully applied to multiple board devices or network equipment using a daisy chain system or stacking method as described above.

1 is a conventional system serial number assignment system and connection configuration applied to the present invention.

2 is a serial number assignment system and connection diagram of a daisy chained system according to the present invention.

<Description of the symbols for the main parts of the drawings>

System: 10, 20, 30, 100, 200, 300, 400

12, 22, 32, 120, 220, 320, 420: input connector

14, 24, 34, 130, 230, 330, 430: output connector

16, 26, 36: Dip Switch

110, 210, 310, 410: system ID detector

Claims (5)

In a daisy chained system, An input connector for receiving an ID related signal, an output connector for outputting the ID related signal to a next subsystem, and detecting an ID of the corresponding system according to a signal received from the input connector, and using the detected ID later. A plurality of systems comprising a system ID detector for storing a plurality of ID signals, and a plurality of ID related signal lines connecting the input connector and the output connector; And a cable for daisy chaining the plurality of systems. 2. The serial numbering system of claim 1, wherein the input connector has a first signal line connected to a power supply (Vcc) terminal and a last signal line connected to a ground (GND) terminal. 2. The serial number of a daisy chained system according to claim 1, wherein the plurality of ID related signal lines must be pre-assigned on the printed circuit board by the total number of systems +1 to generate serial numbers of the respective subsystems. Assignment system. The method of claim 1, wherein when the first subsystem of the daisy chained system is configured as a master system, the subsystems in which the power is turned on even if the power of other subsystems are turned off are not connected to the original connection order. Depending on which serial number you receive, the daisy-chained system's serial number assignment system. Stacking multiple daisy chained systems or multiple identical systems to form one entire system; Turning on each system power supply in the entire system; Connecting an input connector and an output connector on a printed circuit board in each of the power-on systems; All signals are connected through the cable of the entire system and through the input connector and the output connector such that only one of the pins of the input connector of each system is high; Setting a value of the high pin to a register of a system ID detector; And And each system recognizes the value of the register as its own ID number.