KR100766090B1 - Effective implementation scheme of wireless network using mirror image technique and method thereof - Google Patents

Abstract

A wireless bridge apparatus using mirror image technique and a method for realizing a wireless network using the same are provided to enable a first wireless 1394 bridge to receive a transmitting signal or a stream signal from at least one of a 1394 device1-1 and a 1394 device1-2 within a first local cluster to one of a 1394 additional device1-1 and a 1394 additional device1-2 mapped within the first wireless 1394 bridge, and transmit the transmitting signal or the stream signal to a corresponding device between a 1394 device2-1 and a 1394 device2-2 within a second local cluster, thereby enabling communication among all 1394 devices connected to each other by wireless. A 1394 additional device is a 1394a physical layer chip and a 1394a link layer chip used in mirror image technique. A first control unit(120) performs the mapping of redundant 1394 additional devices equipped with a first wireless 1394 bridge(110) and 1394 devices positioned at a second local cluster(200) one to one. A second control unit(220) performs the mapping of a 1394 additional device2-1(240) and a 1394 device1-1(160) and the mapping of a 1394 additional device2-2(250) and a 1394 device1-2(170).

Description

Effective implementation scheme of wireless network using mirror image technique and method

1 is a block diagram provided to explain a wireless bridge device using a mirror image technique according to an embodiment of the present invention, and

2 is a flowchart provided to explain a method for implementing a wireless network using a mirror image technology according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: first local cluster 110: first wireless 1394 bridge

120: first control unit 130: first communication interface

140: 1394 empty device 1-1 142: physical layer 1-1

144: connection layer 1-1 150: 1394 empty device 1-2

152: physical layer 1-2 154: connection layer 1-2

160: 1394 device 1- 1 170: 1394 device 1-2

The present invention relates to a wireless bridge device and a wireless network implementation method using the same, and more particularly, to a wireless bridge device using a mirror image technology and a wireless network implementation method using the same.

A "wireless bridge device" refers to a device that wirelessly implements network functions using a communication protocol.

A representative example of a wireless bridge device is a wireless 1394 bridge.

In general, a 1394 bridge used in a wireless 1394 network must, in addition to the various functions defined in the 1394.1 bridge standard document, perform device detection and bridge sinks in particular.

However, a 1394 bridge physical layer chip and a link layer chip that perform a 1394.1 bridge function have not been developed at present. And, some 1394-related chip makers supply only 1394a chips, not 1394. Therefore, the 1394 bridge is only defined in the standard document and is not actually developed.

Here, 1394a means 1394-2000 which is the revised edition of 1394 completed in 2000.

In addition, the device detection function, as defined in the 1394.1 standard document, means that the 1394 bridge detects all 1394 devices connected wirelessly and shares this information. In addition, the bridge sink function means that a 1394 bridge is a destination of a signal transmitted from a 1394 device in order to transmit a signal to a 1394 device connected to another 1394 bridge that is connected wirelessly to a 1394 device connected to one 1394 bridge. It identifies a node ID and sends it to another 1394 bridge connected wirelessly at the same time it receives it.

Therefore, a technique for implementing a 1394 bridge function required for a wireless 1394 network without using a 1394 bridge-related physical layer and a connection layer defined in an undeveloped 1394.1 bridge standard document is required.

Accordingly, an object of the present invention is to provide a 1394 bridge physical layer currently commercially available to implement the 1394 bridge function required for a wireless 1394 network without using the 1394 bridge-related physical layer and the connection layer defined in the 1394.1 bridge standard document. An object of the present invention is to implement a wireless 1394 network using a mirror image technology based on a physical layer chip and a link layer chip.

In order to achieve the above object, a wireless bridge device using a mirror image technology and a method for implementing a wireless network using the same have at least one additional node and include at least one node and at least one node provided in an external wireless network. It includes a control unit for mapping a blank node 1: 1.

Preferably, the empty node includes a 1394a device in which a 1394a physical layer and a 1394a link layer chip are embedded.

More preferably, the bridge includes a wireless 1394 bridge that performs a device detection function and a bridge sync function through wireless communication under the control of the controller.

In addition, the number of the one or more empty nodes preferably includes the same as the number of one or more nodes provided in the external device.

Here, it is preferable to include a step of embedding one or more empty nodes, and mapping one or more nodes and one or more public nodes in a one-to-one manner provided in an external wireless network.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

1 is a block diagram provided to explain a wireless bridge device using a mirror image technique according to an embodiment of the present invention.

Referring to FIG. 1, a wireless bridge device includes a first local cluster 100 and a second local cluster 200.

The first local cluster 100 has a first wireless 1394 bridge 110, a 1394 device 1-1 160, and a 1394 device 1-2. The first wireless 1394 bridge 110 may include a first control unit 120, a first communication interface 130, a 1394 empty device 1-1 140, a physical layer 1-1 142, and a connection layer 1-1. 144, 1394 empty device 1-2 (150), physical layer 1-2 (152), and connection layer 1-2 (154).

The second local cluster 200 also includes a second wireless 1394 bridge 210, a 1394 device 2-1 260, and a 1394 device 2-2 270. The second wireless 1394 bridge 210 may include a second control unit 220, a second communication interface 230, a 1394 empty device 2-1 240, a physical layer 2-1 242, and a connection layer 2-1. 244, 1394 empty device 2-2 (250), physical layer 2-2 (252), and connection layer 2-2 (254).

However, other components that may be included in the wireless bridge device are excluded from the drawings and only those components necessary for describing the present invention will be shown.

The first local cluster 100 is formed by connecting the first wireless 1394 bridge 110 with the 1394 device 1-1 160 and the 1394 device 1-2 through the 1394 bus. A small group of networks.

Similarly, the second local cluster 200 connects the second wireless 1394 bridge 210 with the 1394 device 2-1 260 and the 1394 device 2-2 270 via the IEEE 1394 bus. It is a small network group formed.

The first communication interface 130 interconnects the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 through communication with the second communication interface 230.

Similarly, the second communication interface 230 interconnects the second wireless 1394 bridge 210 and the first wireless 1394 bridge 110 through communication with the first communication interface 130.

The first wireless 1394 bridge 110 detects the number of all 1394 devices connected through another IEEE 1394 bus with another wireless 1394 bridge in another cluster through a communication interface.

In other words, the first wireless 1394 bridge 110 may include a first communication interface 130 provided in the first wireless 1394 bridge 110 and a second communication interface 230 provided in the second wireless 1394 bridge 210. Detects the 1394 device 2-1 260 and the 1394 device 2-2 270 that are connected to the second wireless 1394 bridge 210 and the IEEE 1394 bus in the second local cluster 200 through do.

Similarly, the second wireless 1394 bridge 210 may include a second communication interface 230 provided in the second wireless 1394 bridge 210 and a first communication interface 130 provided in the first wireless 1394 bridge 110. Through communication, the first local cluster 100 detects the 1394 device 1-1160 and the 1394 device 1-2 170 connected to the first wireless 1394 bridge 110 through the IEEE 1394 bus.

In addition, the first wireless 1394 bridge 110 includes 1394 additional devices equal to the number of 1394 devices included in another wirelessly connected local cluster.

In addition, the second wireless 1394 bridge 210 is provided with the same number of 1394 additional devices as the number of 1394 devices included in another wirelessly connected local cluster.

Here, the 1394 additional device refers to a 1394a physical / link chip to be used in the mirror image technology, which is the core of the present invention. That is, the 1394 empty device 1-1 140 has a physical layer 1-1 142 and a connection layer 1-1 144, and the 1394 empty device 1-2 (150) has a physical layer 1-2 (152). ) And a connection layer 1-2 (154). In addition, the 1394 empty device 2-1 240 has a physical layer 2-1 (242) and a connection layer 2-1 (244), and the 1394 empty device 2-2 (250) has a physical layer 2-2 (252). ) And a connection layer 2-2 (254).

The mirror image technology will be described later.

In other words, the first wireless 1394 bridge 110 includes two 1394 devices corresponding to two devices (1394 device 2-1 260 and 1394 device 2-2 270) located in the second local cluster 200. Blank devices 1394 blank device 1-1 140 and 1394 blank device 1-2 (150) are provided.

In addition, the second wireless 1394 bridge 210 includes two 1394 holes corresponding to two devices (1394 device 1-1 160 and 1394 device 1-2 170) located in the first local cluster 100. Devices 1394 empty device 2-1 240 and 1394 empty device 2-2 250 are provided.

That is, the wireless 1394 bridge according to the present invention includes redundant 1394a physical / link chips.

The first controller 120 controls the first local cluster 100 as a whole. In addition, the second control unit 220 controls the second local cluster 200 as a whole.

The first controller 120 maps the spare 1394 empty devices included in the first wireless 1394 bridge 110 and the 1394 devices located in the second local cluster 200 in a 1: 1 manner. For example, again, the first controller 120 maps the 1394 empty device 1-1 140 to the 1394 device 2-1 260, and the 1394 empty device 1-2 (150) to the 1394 device 2-. Map 2 (270).

In addition, the second controller 220 maps the 1394 empty device 2-1 240 to the 1394 device 1-1 160, and the 1394 empty device 2-2 250 with the 1394 device 1-2. Map it.

As a result, the 1394 empty device 1-1 140 and the 1394 empty device 1-2 (150) are located in the first local cluster 100, but are similar to the 1394 device 2-1 (located in the second local cluster 200). 260 and 1394 device 2-2 (270). The 1394 empty device 2-1 240 and the 1394 empty device 2-2 250 are located in the second local cluster 200, but are like 1394 devices 1-1 160 located in the first local cluster 100. ) And 1394 device 1-2 (170).

That is, each of them operates as if the image of the second local cluster 200 is transferred to the first local cluster 100 as it is, and the image of the first local cluster 100 is transferred to the second local cluster 200 as it is. As it operates as described above, this is defined as a mirror image technology.

Through this mirror image technique, the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 solve the conventional problems of the device sensing function and the bridge sink function.

Specifically, it is as follows.

First, for convenience of description, the 1394 blank device 1-1 140, the 1394 blank device 1-2 150, the 1394 device 1-1 160, and the 1394 device 1-2, respectively, are first localized. Node 3, node 2, node 1, and node 0 of the cluster 100 are also referred to as 1394 empty device 2-1 (240), 1394 empty device 2-2 (250), and 1394 device 2-1 ( 260 and 1394 device 2-2 270 are defined as node 3, node 2, node 1, and node 0 of second local cluster 200, respectively.

First, the device detection function is performed through the following process.

By placing the nodes to be used for the mirror image technique in the first wireless 1394 bridge 110, the number of nodes equal to the number of nodes located in the second local clusters 200, and then mapped 1: 1. Nodes in the wireless 1394 bridge 110 may represent nodes located in the second local cluster 200.

That is, when configuration ROM information of node 0 and node 1 of the second local cluster 200 is mapped to node 2 and node 3 of the first wireless 1394 bridge 110 in a 1: 1 manner, Nodes 0 and 1 of the first local cluster 100 may detect nodes 0 and 1 of the second local cluster 200.

Next, the bridge sync function is performed through the following process.

In the first local cluster 100, to connect to node 0 located in the second local cluster 200, the destination address may be referred to as node 2 of the first wireless 1394 bridge 110, and the second local cluster 200 may be connected. In order to connect to the located node 1, the destination address may be referred to as node 3 of the first wireless 1394 bridge 110, so that the first wireless 1394 bridge 110 is always synchronized.

The above process has been described based on the first wireless 1394 bridge 110, but the same applies to the second wireless 1394 bridge 210.

As described above, the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 of the present invention, while communicating with each other through the first communication interface 130 and the second communication interface 230, the mirror By mapping the image of the empty devices provided in each one with the devices of the other side through the technology, to form a wireless network.

In the above description, for convenience of description, two clusters (the first local cluster 100 and the second local cluster 200) have been described as an example, but the present invention may be applied to three or more clusters. In addition, 1394 devices connected to the 1394 wireless bridge and 1394 empty devices located in the 1394 wireless bridge can also be applied to more than three.

2 is a flowchart provided to explain a method for implementing a wireless network using a mirror image technology according to an embodiment of the present invention.

1 and 2, the first local cluster 100 performs initialization. Specifically, when one or more 1394 devices are newly attached or erased to the first local cluster 100, a local bus reset occurs in the first local cluster 100 to perform 1394 local initialization (S310).

Local initialization means initializing each local cluster. This 1394 local initialization includes tree ID, self ID process, etc., as defined in the IEEE 1394a standard document.

At this time, the first wireless 1394 bridge 110 detects tree ID, self ID process, and configuration ROM information of 1394 devices connected to a local bus. Here, the first wireless 1394 bridge 110 grasps tree ID, self ID process, and configuration ROM information of the 1394 device 1-1160 and the 1394 device 1-2 170.

In addition, the second local cluster 200 also performs initialization, so that the second wireless 1394 bridge 210 performs tree ID, self ID process, and configuration of the 1394 device 2-1 260 and the 1394 device 2-2 270. Get ROM information.

Next, the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 perform mutual communication (S320).

Specifically, the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 communicate with each other through the first communication interface 130 and the second communication interface 230, respectively, to establish a counterpart local cluster ( Exchanges information of all 1394 devices provided in 100).

In other words, the first wireless 1394 bridge 110 communicates with the second wireless 1394 bridge 210 to establish a 1394 device 2-1 260 and a 1394 device 2-2 270 located in the second local cluster 200. Information is provided. In addition, the second wireless 1394 bridge 210 communicates with the first wireless 1394 bridge 110 to display the 1394 devices 1-1 160 and the 1394 devices 1-2 170 located in the first local cluster 100. You are provided with information.

Next, the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 perform mirror image mapping, respectively (S330).

In detail, the first wireless 1394 bridge 110 1: 1 maps the 1394 devices 2-1 260 in the second local cluster 200 to the 1394 blank devices 1-1 140 prepared for the mirror image mapping. The 1394 device 2-2 270 in the second local cluster 200 is mapped to the 1394 empty device 1-2. The second wireless 1394 bridge 210 1: 1 maps the 1394 devices 1-1 160 in the first local cluster 100 to the 1394 blank devices 2-1 240 prepared for the mirror image mapping. The 1394 empty device 2-2 250 maps the 1394 device 1-2 (270) in the first local cluster 200.

When the mirror image mapping is completed, the first wireless 1394 bridge 110 and the second wireless 1394 bridge 210 globally reset the first local cluster 100 and the second local cluster 100 (S340).

Here, a global reset refers to a reset performed by a local cluster to recognize a 1394 empty device mapped 1: 1 in a corresponding wireless 1394 bridge.

After global reset, global initialization is performed (S350).

In other words, the first local cluster 100 performs 1394 initialization again after a global reset, and the 1394 device 2-1 260 and the 1394 device 2-2 270 located in the mirror image mapped second local cluster 200. Recognize). In addition, the first wireless 1394 bridge 110 may include the first wireless 1394 bridge 110 from at least one of the 1394 devices 1-1 160 and the 1394 devices 1-2 170 in the first local cluster 100. When the transmission signal or the stream signal is transmitted to any one of the 1394 empty device 1-1 140 and the 1394 empty device 1-2 (150) mapped therein, the second local cluster 200 using the wireless network is received. By transmitting to the corresponding device of the 1394 device 2-1 (260) and 1394 device 2-2 (270) of the, it is possible to communicate between all 1394 devices connected wirelessly.

As described above, according to the present invention, a wireless IEEE 1394 network using mirror image technology based on currently commercialized IEEE 1394a physical layer chip and link layer chip. By implementing this, it is possible to implement the IEEE 1394 bridge function required for a wireless IEEE 1394 network without using the 1394 bridge-related physical layer and the connection layer defined in the IEEE 1394.1 bridge standard document.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the above-described specific embodiment, the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (5)

Has one or more additional nodes, And a controller for mapping one or more nodes provided in an external wireless network and the one or more empty nodes by 1: 1. And the empty node is an IEEE 1394 empty device in which IEEE 1394a Physical Layer and 1394a Link Layer chips are embedded. delete According to claim 1, The control unit, A wireless bridge device, characterized in that performing a device detection function and a bridge sync function through wireless communication. The method of claim 1, The number of the one or more empty nodes is a wireless bridge device, characterized in that the same as the number of one or more nodes provided in the external device. Embedding one or more additional nodes; And And mapping one or more nodes provided in an external wireless network and the one or more empty nodes in a 1: 1 manner. And the empty node is an IEEE 1394 empty device in which IEEE 1394a Physical Layer and 1394a Link Layer chips are embedded.

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