KR20000034482A - Embodiment method of integrated management environment for ieee p1394 equipment of host computer - Google Patents

Abstract

PURPOSE: An embodiment method of integrated management environment for IEEE P1394 equipment of host computer is provided to easily manage various kinds of IEEE P1394 equipment. CONSTITUTION: An embodiment method of integrated management environment for IEEEP1394 equipment of host computer comprises steps of: determining whether new IEEE P1394 equipment is connected; identifying various functional information and transfer data format information from the connected IEEE P1394 equipment; generating respective functional icon on the basis of the functional information; selecting an application program suitable to a corresponding equipment on the basis of the transfer data format information; and displaying the selected program in a menu format of GUI(Graphic User Interface).

Description

An integrated management environment implementation method of IEEE P1394 devices in a host computer

The present invention relates to a method for managing an IEEE P1394 device of a host computer. In particular, the present invention relates to a method for managing an IEEE P1394 device by displaying application programs of various IEEE P1394 devices in a menu format of a GUI (Graphic User Interface) environment. The present invention relates to an IEEE P1394 device integrated management environment implementation method.

In general, high-performance serial buses that overcome the problems of parallel buses have been widely studied in order to implement high-speed buses required by computer technology.

The high performance serial bus is a digital serial bus standardized by IEEE P1394, and is defined as a node, a module, and a unit.

In the above, the node is an addressable entity, and reset and recognition may be performed independently. A module consists of one or more nodes. A node is a logical addressing concept, whereas a module is a physical package.

In addition, a node is a logical entity with a unique address, which can be independently reset with an ID ROM and a series of standardized control registers. The address space provided by a node may be mapped to one or more units. A unit is a logical object, such as a disk controller, that corresponds to its own I / O driver software.

On the other hand, a device adopting the IEEE P1394 standard interface as described above is commonly referred to as an IEEE P1394 device, and the IEEE P1394 device includes a camera, a camcorder, a digital video cassette recorder (DVCR), a digital television (DTV), and a hard disk drive (HDD). Etc.

The IEEE P1394 device is usually connected to a host computer and operates under the management of the host computer. The host computer includes an add-on card of a programmable communication interface (PCI) type to enable connection of an IEEE P1394 device.

In addition, in order for the host computer to manage the IEEE P1394 device, an application program suitable for the device is required, and the application program is usually provided in a form stored on a floppy disk or CD-ROM at the time of sale of the IEEE P1394 device. Here, the user stores the application program provided at the time of purchase of the device in the host computer, and executes it during the operation of the device to enable management of the IEEE P1394 device by the host computer.

Conventionally, a plurality of IEEE P1394 devices are connected to a host computer, and different types of devices have different application programs for each device. Therefore, in order to use a plurality of IEEE P1394 devices, a user needs to install an application program for each device on the host computer. You must run them separately.

As described above, when various types of IEEE P1394 devices are used, an application program for each device is executed separately on a host computer. Therefore, it is difficult to transfer data between IEEE P1394 devices or to add or integrate new functions. there was.

The present invention has been made to solve the above problems, each time the IEEE P1394 device is connected automatically generates an icon for each function of the device, by selecting an application program for the device in the form of a menu of GUI environment An object of the present invention is to provide a method for implementing an IEEE P1394 device integrated management environment of a host computer to facilitate the integrated management of various IEEE P1394 devices by displaying the same.

In order to achieve the above object, an IEEE P1394 device integrated management environment implementation method of a host computer according to the present invention provides a method for managing an IEEE P1394 device by using a pre-provided application program. Determining whether a new IEEE P1394 device is connected, and querying the device for various types of function information and transmission data format information, and based on the function information found from the IEEE P1394 device. Generating an icon for each function of the device, selecting an application program suitable for the device from among various application programs provided in advance based on the transmission data format information found from the IEEE P1394 device, and selecting the selected application program. GUI environment And displaying the menu in a menu format.

1 is a physical topology of the IEEE P1394 standard high performance serial bus,

2 is a protocol stack of the IEEE P1394 standard high performance serial bus,

3 is a configuration diagram of a system to which an embodiment of the present invention is applied;

4 is an exemplary diagram of a GUI menu according to the present invention;

5 is a flowchart illustrating an implementation procedure of an IEEE P1394 device integrated management environment of a host computer according to an embodiment of the present invention.

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

10: host computer 11: IEEE P1394 standard interface device

20-1 to 20-n: IEEE P1394 device

30-1 to 30-n: Transmission cable of IEEE P1394 method

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

In order to facilitate the understanding of the present invention, the IEEE P1394 standard high performance serial bus applied to the IEEE P1394 device will be briefly described.

The physical topology of the IEEE P1394 standard high performance serial bus is divided into a serial bus in a backplane environment and a serial bus in a cable environment as shown in FIG. 1, and the serial buses of different environments are connected to the bridges BRIDGE 120 and 140. Is connected by.

In FIG. 1, the CPU 111, the memory MEMORY 112, the I / O 113, and the CPU 114 included in the systems 110 and 130 of the backplane environment are interconnected through the serial bus 115. have. Input / output devices (I / O) 150 and 160 in a cable environment are interconnected via serial bus 154, and cable media 152, 153 and 154 connect ports of different nodes. Here, the cable mediums 152 to 154 consist of two pairs of conductor cables for signal transmission and one pair of cables for power supply.

2 is a protocol stack of the IEEE P1394 standard high performance serial bus, which is layered into a physical layer 220, a link layer 230, and a transaction layer 240; The serial bus management layer 210 manages layered protocols.

The physical layer 220 includes connectors / media, arbitration, bus initialization, data resynch, signal levels, encode / decode. ) Function.

The link layer 230 includes a packet transmitter, a packet receiver, and a cycle control function.

The serial bus management layer 210 includes a node controller 211 including a standard CSR 211a, an isochronous resource manager 212 including an isochronous CSR 212a, and a management CSR. There is a Bus Manager (213) function, including (213a).

In addition, request (* .req), acknowledgment (* .conf), indication (* .ind), and response (* .resp) primitives are transferred between layers to exchange information. For example, PH_DATA.ind, PH_CLOCK.ind, and PH_ARB.conf primitives are transmitted from the physical layer 220 to the link layer 230, and PH_DATA.req, from the link layer 230 to the physical layer 220. The PH_ARB.req primitive is passed.

In the layered protocol as described above, the link layer 230 provides a half-duplex data packet transmission service. Here, the operation of transmitting one packet is called a subaction, and such subactions include asynchronous subactions and isochronous subactions. The asynchronous subaction carries variable length data and a few bytes of transaction layer information by an explicit address, and a response to the transferred operation is required. On the other hand, the isochronous subaction transmits variable length data at regular intervals by a simple address, and does not need a response to the transferred operation.

In addition, a packet transmitted through the link layer 230 includes an asynchronous packet and an isochronous packet, and each packet is a sequence of aligned quadlets (32 bits).

Details of such high performance serial buses are described in the IEEE P1394 standard book published in November 1995.

3 is a configuration diagram of a system to which an embodiment of the present invention is applied, and the system includes a host computer 10 and n IEEE P1394 devices 20-1, 20-2, 20-3, ..., 20-n. It consists of

The host computer 10 includes an IEEE P1394 standard interface device 11, and contains an application program for each IEEE P1394 device 20-1 to 20-n.

The n IEEE P1394 devices 20-1 through 20-n transmit the IEEE P1394 device through the IEEE P1394 transmission cable 30-1, 30-2, 30-3, ..., 30-n. Each of the IEEE P1394 standard interface devices (not shown) is connected to the P1394 standard interface device 11.

A process of the host computer 10 implementing the integrated management environment of the n IEEE P1394 devices 20-1 to 20-n in the system configured as described above will be described in more detail with reference to the flowchart shown in FIG.

First, the host computer 10 determines whether a new IEEE P1394 device is connected to its IEEE P1394 standard interface device 11 via a transmission cable (S501).

As a result of the determination in step S501, when a new IEEE P1394 device is connected, the host computer 10 uses the vendor information of the device and the commands defined in the IEEE P1394 standard interface command set to control the device with various function information (control). A function (control function), status, and transmission data format information (MPEG, DV, JPEG, etc.) are queried and found (S502).

After the step S502, the host computer 10 generates an icon for each function of the corresponding device based on the function information found from the corresponding device (S503), and based on the transmission data format information found out from the corresponding device, An application program (decoder, display routine, other application program) suitable for the corresponding device is selected among the branch application programs (S504).

After the step S504, the host computer 10 displays the selected application program in a menu format of a GUI environment (S505).

The host computer 10 repeats steps S501 to S505 whenever a new IEEE P1394 device is connected to implement the integrated management environment of each device in a GUI menu format on the screen. As shown in FIG. 3, when n IEEE P1394 devices 20-1 to 20-n are connected to the host computer 10, the host computer 10 executes steps S501 to S505 for each IEEE P1394 device 20-. Each time 1 to 20-n is connected, the data is repeatedly executed, that is, n times to implement the integrated management environment of the devices 20-1 to 20-n.

For example, when a DVCR, a DTV, an HDD, a camcorder, and a camera, which are types of IEEE P1394 devices, are connected to the host computer 10 in order, a menu of a GUI environment as shown in FIG. 4 is displayed on the screen of the host computer 10. When the user double-clicks the icon of the device to be operated by using a mouse (not shown) provided in the host computer 10, each function of the selected device is not displayed on the screen. It is displayed as an icon. In this case, when the user double-clicks the icon of the desired function by using the mouse, the selected device performs the selected function.

As described above, in the present invention, since the host computer displays application programs of various IEEE P1394 devices connected to the user on the screen in the form of a menu of GUI environment, the user can operate each device more easily and conveniently through the menu of GUI environment. In addition, the data transfer between devices, the addition of new functions, and the integrated management of the entire device can be made easier.

Claims (1)

In the method for the host computer to manage the IEEE P1394 device using a pre-supplied application program, Determining whether a new IEEE P1394 device is connected; If the new IEEE P1394 device is connected as a result of the determination, querying the device for various function information and transmission data format information; Generating an icon for each function of the corresponding device based on the function information found from the IEEE P1394 device; Selecting an application program suitable for the device from among various application programs provided in advance based on the transmission data format information found from the IEEE P1394 device; And displaying the selected application program in the form of a menu of a GUI environment.