JP3508060B2 - Infrared communication method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an infrared communication system, and more particularly to a communication system using infrared rays in an infrared LAN (local area network) or the like.

[0002]

2. Description of the Related Art In addition to a PC (personal computer) or a workstation, various peripheral devices such as a printer, an image scanner and a facsimile (FAX) machine are connected to a LAN. Such peripherals are usually connected using a cable with connectors on both ends. However, as the number of peripheral devices increases, the number of cables also increases, and when the user walks in the office, he or she may get caught in the cables, destroying the peripheral devices or losing data. Further, it is necessary to disconnect and reconnect a large number of cables each time the office layout is changed, which is extremely inconvenient. Therefore, it has been proposed that data is transmitted and received between the PC and peripheral devices by infrared (or wireless) communication, and a cable is unnecessary. A conventional example of this wireless communication technique is disclosed in, for example, Japanese Patent Laid-Open No. 10-117207, "Mobile terminal connection method and network router".

FIG. 7 shows the configuration of such a conventional technique. This system includes a terminal 1, an infrared LAN access point 2, a LAN 8 and a server 11.
The infrared LAN access point 2 and the server 11 are
It is connected by the LAN 8 and is a so-called LAN environment. The terminal 1 and the infrared LAN access point 2 communicate by infrared rays. Terminal 1 uses IrDA (Infrared Data)
Association) protocol driver 3, infrared LAN driver 4, TCP / IP (Transport Control Protocol)
/ Internet Protocol) A protocol stack 9 and an application (hereinafter referred to as AP) 10 are included.
The infrared LAN access point 2 is IrDA5, Ir
A LAN 6 and a LAN network interface (hereinafter referred to as NIC) 7 are included. This infrared LAN
The access point 2 and the server 11 are given unique MAC (Media Access Control) addresses 12 and 13 respectively.

The function of each part of the conventional system configuration shown in FIG. 7 will be briefly described. The terminal 1 is a terminal equipped with an infrared communication device. The infrared LAN access point 2 is a network adapter of the terminal 1 having an infrared link. The LAN 8 is a LAN environment to which the infrared LAN access point 2 is connected. The IrDA protocol driver 3 performs infrared communication on the terminal 1. The infrared LAN driver 4 is an IrLAN on which the infrared LAN communication protocol defined by IrDA operates on the IrDA protocol driver 3 described above. Here, IrDA is a standard for data communication using infrared rays. TCP
The TCP / IP protocol operates in the / IP protocol stack 9. The AP 10 is an application that communicates with the server 11 using TCP / IP.

Similarly, the IrDA 5 performs infrared communication on the infrared LAN access point 2. IrLAN6
Operates with the infrared LAN communication protocol defined by IrDA. The NIC 7 connects to a LAN environment. The server 11 is a server connected to the LAN environment. MA
The C address 12 is an address given to the infrared LAN access point 2. In addition, MAC address 13
Is the address given to the server 11. Therefore,
The system of FIG. 7 is a system in which the terminal 1 connects and communicates with the server 11 connected to the LAN 8 via the infrared LAN access point 2. Here, the IrLAN 4 of the terminal 1 is an IrLAN client, an infrared LAN
The IrLAN 6 of the access point 2 is called an IrLAN provider.

Next, FIG. 8 is a flow chart for performing infrared LAN communication in the conventional system shown in FIG. When performing infrared LAN communication, an operation of finding an infrared LAN access point and an operation of actually using an application for communication are required. Figure 8
(A) is a flowchart showing an operation for finding the infrared LAN access point 2. On the other hand, FIG. 8 (B)
6 is a flowchart showing an operation using the AP 10. First, with reference to FIG. 8 (A), a flow chart of an operation for finding the infrared LAN access point 2 will be described.

First, the user gives an instruction for a process of discovering the infrared LAN access point 2 (step 201). The process of discovering the infrared LAN access point 2 is started from the terminal 1 side (step 202). If the infrared LAN access point 2 cannot be found, the infrared LAN access point discovery process is performed again (step 20).
3). This infrared LAN access point discovery processing is performed at regular intervals until the user gives a cancel instruction. Infrared LA using AP10 when the infrared LAN access point 2 is discovered and communication is possible
N communication is performed.

Next, a series of communication operations using an application will be described with reference to the flowchart of FIG. First, the AP 10 that performs communication is activated (step 211). Next, the connection with the server 11 is performed (step 212), and the connection with the server 11 is completed (step 213). Therefore, data is transmitted and received (step 2)
14). Then, when the communication is completed, the AP 10 is terminated (step 215). As described above, in order to communicate with the conventional system, it was necessary to discover the infrared LAN access point 2 and then operate the AP 10.

FIG. 9 is a detailed flowchart of the internal operation of the conventional system shown in FIG. The operation inside the terminal 1 when performing infrared LAN communication in the conventional system will be described. In the conventional system, in the initial state, the terminal 1
Infrared LAN driver 4 is not resident. TCP
/ IP protocol stack 9 is an MA for communication.
Since the C address 12 has not been acquired and the infrared LAN driver 4 does not exist, infrared LAN communication cannot be performed. The infrared LAN driver 4 instructs the user to perform a discovery process of the infrared LAN access point 2 (step 30).
1) The process of finding the infrared LAN access point 2 is performed (step 302). When the infrared LAN access point 2 is found (step 303), the infrared LAN driver 4 of the terminal 1 is loaded (step 304).

Immediately after loading the infrared LAN driver 4,
The infrared LAN driver 4 registers the interface on the TCP / IP protocol stack 9 side (step 3).
11). The infrared LAN driver 4 receives a driver start request from the TCP / IP protocol stack 9 side (step 310). A MAC address is requested from the TCP / IP protocol stack 9 (step 30).
5). The infrared LAN driver 4, which receives the request for the MAC address from the TCP / IP protocol stack 9, acquires the MAC address 12 from the infrared LAN access point 2 (step 306). Infrared LAN driver 4
Notifies the TCP / IP protocol stack 9 of the MAC address 12 of the infrared LAN access point 2 (step 307). As a result, the MAC address 12 of the infrared LAN access point 2 acquired by TCP /
The IP protocol stack 9 is ready for infrared LAN communication. After that, the AP 10 is activated on the terminal 1 (step 308). Therefore, from terminal 1 to infrared LAN
It becomes possible to communicate with the server 11 connected to the LAN 8 through the access point 2 (step 309).

[0011]

In the above-mentioned conventional system, the infrared LAN driver 4 is resident, and the AP 10 using infrared communication cannot start the communication. Before starting the AP 10 using infrared communication, the infrared LAN access point 2 is found separately by the user and the infrared LAN driver 4 is loaded. Then, after the MAC address 12 of the infrared LAN access point 2 is acquired / notified, and the TCP / IP protocol stack 9 of the terminal 1 is set to the infrared communication enabled state, the AP 10 using the infrared communication is used. There is such a problem.

First, it takes time to load the infrared LAN driver. The reason is that the infrared LAN driver must be loaded and the MAC address must be acquired in order to load the infrared LAN driver.
Secondly, it takes time and effort to perform infrared communication. The reason is AP (application) that uses infrared communication
This is because it is necessary to perform an operation of discovering the infrared LAN access point separately from the activation of the. Third, there is wasted infrared power consumption. The reason is that the infrared LAN access point discovery processing is performed regardless of whether the AP that performs infrared communication performs communication.

[0013]

An infrared communication system of the present invention is a communication system between an infrared LAN process point and a terminal equipped with an infrared communication device having an infrared link, and the terminal is defined by IrDA. The infrared LAN driver that operates on the IrLAN protocol resides and
The end is an IrDA protocol driver for infrared communication,
Infrared LAN communication on this IrDA protocol driver
Infrared LAN driver that protocol operates, TCP /
TCP / IP protocol host running IP protocol
, This TCP / IP protocol stack and infrared
There is a virtual MAC address used between the line LAN drivers.
To do.

[0014] According to a preferred embodiment of an infrared communication method of the present invention, in order to reside infrared LAN driver on the terminal, the conversion processing of the MAC address carried. When the terminal starts communication with the application, the infrared LA
N access point discovery processing is performed.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The configuration and operation of a preferred embodiment of an infrared communication system according to the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 1 is a system configuration diagram of an infrared communication system according to the present invention. For convenience of explanation, the same reference numerals are used for the components corresponding to the components of the conventional system described above. The system shown in FIG.
Similar to the conventional system described above, the terminal 1 and the infrared LAN
The access point 2, the LAN 8 and the server 11 are included. The terminal 1 is an IrDA protocol driver 3 and an infrared LAN provided with a virtual MAC address 40.
It includes a driver 4, a TCP / IP protocol stack 9 and an application (AP) 10. Infrared L
AN access point 2 is IrDA5, IrLAN
6, a LAN network interface (NIC) 7 is included. The infrared LAN access point 2 and the server 11 are connected to the LAN 8 and are given unique MAC addresses 12 and 13, respectively. Furthermore,
The terminal 1 and the infrared LAN access point 2 are connected by infrared communication.

In FIG. 1, a terminal 1 is a terminal equipped with an infrared communication device. Infrared LAN access point 2
Is a network adapter of the terminal 1 having an infrared link. LAN8 is infrared LAN access point 2
Is a LAN environment to which is connected. The IrDA protocol driver 3 performs infrared communication on the terminal 1. Infrared LA
The N driver 4 uses the IrDA protocol driver 3
The infrared LAN communication protocol defined by rDA operates. The TCP / IP protocol stack 9 uses TCP / IP
The IP protocol works. AP10 is TCP / IP
Is an application that communicates with the server 11 using.

Similarly, the IrDA 5 performs infrared communication on the infrared LAN access point 2. IrLAN6
Operates with the infrared LAN communication protocol defined by IrDA. NIC7 is a LAN that connects to a LAN environment
It is a network interface. The server 11
It is a server connected to the LAN 8. MAC address 1
2 is an address given to the infrared LAN access point 2. The MAC address 13 is an address given to the server 11. Therefore, in the system shown in FIG. 1, the terminal 1 connects and communicates with the server 11 connected to the LAN 8 via the infrared LAN access point 2.

As is apparent from the above, the infrared communication system of the present invention is characterized in that the infrared LAN driver 4 operating in the infrared LAN communication protocol in the terminal 1 is made resident in the infrared LAN communication environment. In order to make the infrared LAN driver 4 resident on the terminal 1, the MA
It is characterized in that conversion processing of the C address is performed.

Next, FIG. 2 shows a flowchart for performing infrared LAN communication by the infrared communication system of the present invention shown in FIG. In the infrared communication system of the present invention, the operation for performing infrared LAN communication is as shown in the flowchart of FIG. 2 by making the infrared LAN driver 4 resident. That is, first, the AP 10 that performs communication is activated (step 5).
01). Next, the server 11 connected to the LAN 8 is connected (step 502). It is determined whether or not the connection between the LAN 8 and the server 11 is completed (step 503).
When the connection is completed, data is transmitted and received (step 5)
04). Finally, when the communication is completed, the AP 10 is ended (step 505).

In the infrared communication system of the present invention, by making the infrared LAN driver 4 resident on the terminal, the following becomes possible. That is, since the infrared LAN driver 4 is resident, it is not necessary to load the infrared LAN driver 4 by the user's operation. Therefore, useless infrared LAN
The discovery process of the access point 2 is eliminated, and the power consumption of infrared rays is reduced.

The internal operation of the preferred embodiment of the infrared communication system according to the present invention shown in FIG. 1 will now be described in detail with reference to the sequence diagrams of FIGS. 3, 4 and 5. Infrared L
The operation until the AN driver 4 is loaded and made resident in the terminal 1 will be described with reference to FIGS. 1 and 3. First,
When the terminal 1 is started up, the infrared LAN driver 4 is loaded (step 601). Next, the infrared LAN driver 4 registers the interface on the TCP / IP protocol stack 9 side (step 602). Infrared LAN
The driver 4 receives a driver start request from the TCP / IP protocol stack 9 side (step 603).
Immediately after loading the infrared LAN driver 4, the infrared LAN
The driver 4 receives from the TCP / IP protocol stack 9 side an information acquisition request for the MAC address of its own station (step 604). The infrared LAN driver 4 notifies the internal virtual MAC address 40 to the TCP / IP protocol stack 9 side (step 605). The infrared LAN access point 2 is not discovered from the terminal 1 (step 606). The TCP / IP protocol stack 9 becomes virtually communicable by acquiring the virtual MAC address 40.

Next, the operation until the AP 10 is activated and the connection is established will be described with reference to FIGS. 1 and 4. First,
The AP 10 used for infrared LAN communication is activated (step 701). The AP 10 requests the TCP / IP protocol stack 9 to connect to the server 11 in the LAN 8 environment (step 702). The TCP / IP protocol stack 9 sends a connection request to the infrared LAN driver 4 (step 703). Infrared LA accepting connection request
The N driver 4 starts the process of finding the infrared LAN access point 2 (step 704). This step 7
When the infrared LAN access point 2 is found at 04, the infrared LAN driver 4 acquires the MAC address 12 of the infrared LAN access point 2 (step 705). IrLA of infrared LAN access point 2
Connect N6 and control channel. The control channel is connected for control of the data channel (step 706).

Next, the infrared LAN driver 4 acquires the provider information from the IrLAN 6 of the infrared LAN access point 2 (step 707). When acquiring the provider information, the frame type and IrLAN version supported by the provider are acquired. Next, infrared L
The AN driver 4 acquires media information from the IrLAN 6 of the infrared LAN access point 2 (step 708). Acquire additional information on the frame type by acquiring media information. Next, the infrared LAN driver 4
The IrLAN 6 of the infrared LAN access point 2 is connected to the data channel (step 709). The data channel is connected for data transmission and reception. Next, the infrared LAN driver 4 requests a filter configuration from the IrLAN 6 of the infrared LAN access point 2 (step 710). Set the filter on request for filter configuration. With this, I
The rLAN protocol connection is complete. Next, AP10
And the server 11 in the LAN8 environment (step 7).
11). When the connection is completed, data can be transmitted and received, and infrared LAN communication can be performed (step 712).

Next, the operation of transmitting and receiving data from the AP 10 will be described with reference to FIGS. 1 and 5. Also, the MA in the infrared LAN driver 4 at the time of data transmission / reception
A method of converting the C address will also be described with reference to FIG. Data transmission is performed as follows. Data is transmitted from the AP 10 to the server 11 (step 80).
1). The transmission request from the AP 10 is sent to the infrared LAN driver 4 via the TCP / IP protocol stack 9.
The transmission request goes up (step 802). The TCP / IP protocol stack 9 uses the previously notified virtual MAC address 40 to perform transmission processing to the infrared LAN driver 4. The infrared LAN driver 4 copies the received transmission data to its own buffer (step 80).
3). The infrared driver 4 converts the virtual MAC address 40 used in the transmission from the TCP / IP protocol stack 9 into the MAC address 12 of the actual transmission source used on the IrDA protocol driver 3 side (step 804).

Next, with reference to FIG. 6, a method of converting the MAC address at the time of data transmission by the infrared LAN driver 4 will be described. FIG. 6A shows the TCP / IP protocol stack 9 and the infrared LAN driver 4 and the infrared LAN.
A frame structure of an Ethernet (registered trademark) frame 901 transmitted and received by the driver 4-IrDA (LAN environment) 3 is shown. Generally, the Ethernet frame 901 is the MA of the communication partner.
It is composed of a C address 921, a transmission source MAC address 922, a frame type 923, user data 924 and a frame check sequence 925. FIG. 6 (C)
The infrared LAN driver 4 shown in FIG.
It is an Ethernet frame 902 received from the CP / IP protocol stack 9. Infrared LA when sending data
In the Ethernet frame 902 that the N driver 4 receives from the TCP / IP protocol stack 9, the MAC address 13 of the server 11 is set as the destination address 921 and the virtual MAC address 40 is set as the source address 922. In step 903, the infrared LAN driver 4
Is the virtual MA set at the source address 922.
The C address 40 and the MAC address 12 of the actual infrared LAN access point 2 are converted, reset, and Ir.
It is transmitted to the DA protocol driver 3 side. FIG. 6 (D)
Indicates an Ethernet frame 904 received by the IrDA protocol driver 3 from the infrared LAN driver 4. The data whose MAC address has been converted by the infrared LAN driver 4 is transmitted to the server 11 (step 805).

On the other hand, data reception is performed as follows. First, when the terminal 1 receives data (step 80)
6), a data reception request is sent to the infrared LAN driver 4 (step 807). The infrared LAN driver 4 is Ir
Data reception is requested to DA3 (step 808). Since the MAC address of the data received in step 808 is the actual MAC address 12 of the infrared LAN access point 2, the infrared LAN driver 4 uses TCP / TCP
It is converted to the previously notified virtual MAC address 40 used on the IP protocol stack 9 side (step 80).
9). 6C shows an Ethernet frame 905 that the LAN driver 4 receives from the IrDA protocol driver 3 side when receiving data. The infrared LAN driver 4 receives the Ethernet frame 905 from the IrDA protocol driver 3 side at the time of data transmission.
The MAC address 12 of the actual infrared LAN access point 2 is set to the destination address 921, and the MAC address 13 of the server 11 is set to the transmission source address 922.
The infrared LAN driver 4 is the MAC of the infrared LAN access point 2 set to the destination address 921.
The address 12 and the virtual MAC address 40 are converted, reset, and transmitted to the TCP / IP protocol stack 9 side (step 906). FIG. 6B shows TCP / IP.
An Ethernet frame 907 received from the infrared LAN driver 4 by the protocol stack 9 is shown.

The data whose MAC address has been converted by the infrared LAN driver 4 is passed to the TCP / IP protocol stack 9 side (step 810). The AP 10 requests data reception and receives the data received by the terminal 1 (step 811). Thus, the infrared communication LAN driver 4 of the present invention operates.

The configuration and operation of the preferred embodiment of the infrared communication system according to the present invention have been described above in detail. However, it should be noted that such an embodiment is merely an example of the present invention and does not limit the present invention in any way. Those skilled in the art can easily understand that various modifications and changes can be made according to a specific application without departing from the gist of the present invention.

[0030]

As is clear from the above description, according to the infrared communication system of the present invention, the following remarkable practical effects can be obtained. First, it eliminates the need to load the infrared LAN driver. The reason is that the infrared LAN driver is resident. Second, useless infrared LA
N access point discovery processing is eliminated, and infrared power consumption is reduced. The reason is that the infrared LAN driver is made resident and the infrared LAN access point discovery process is performed when the application starts communication. Third, it saves time before using the application. The reason is that there is no need to make the infrared LAN driver resident and perform the infrared LAN access point discovery process from the UI before using the upper application.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a preferred embodiment of an infrared communication system according to the present invention.

FIG. 2 is an operation flowchart of infrared LAN communication of the infrared communication system shown in FIG.

FIG. 3 is an internal operation sequence of the infrared communication system shown in FIG.

FIG. 4 is an internal operation sequence of the infrared communication system shown in FIG.

5 is a data transmission and reception operation sequence of the infrared communication system shown in FIG.

FIG. 6 is an explanatory diagram of a frame format and a MAC address conversion method for data transmission / reception according to the present invention.

FIG. 7 is a configuration diagram of a conventional infrared communication system.

FIG. 8 is an infrared ray L of the conventional infrared communication system shown in FIG.
It is an operation flowchart of AN communication.

9 is a detailed flowchart of the internal operation of the conventional infrared communication system shown in FIG.

[Explanation of symbols]

1 terminal 2 Infrared LAN access point 3 IrDA protocol driver 4 Infrared LAN driver 5 IrDA 6 IrLAN 7 LAN network interface (NIC) 8 LAN 9 TCP / IP protocol stack 10 Application (AP) 11 servers 12, 13 MAC address 40 virtual MAC address

Claims (3)

(57) [Claims] 1. An infrared communication system between an infrared LAN access point and a terminal equipped with an infrared communication device having an infrared link, wherein the terminal is resident with an infrared LAN driver operating on the IrLAN protocol defined by IrDA. and, the terminal, IrDA protocol Dora performing infrared communication
Iva, infrared LAN on the IrDA protocol driver
Infrared LAN driver that operates communication protocol, TC
TCP / IP protocol operating P / IP protocol
Stack, said TCP / IP protocol stack and
Virtual MAC add used between the infrared LAN drivers
Infrared communication method characterized by having a reply . 2. The infrared LAN driver on the terminal
In order to make it resident, it is necessary to convert the MAC address.
The infrared communication system according to claim 1, wherein: 3. The terminal starts communication with an application
When you do, the location of discovery of the infrared LAN access point
Infrared ray according to claim 1 or 2, characterized in that
Line communication method.