JP2004015181A - Protocol conversion module, and data transfer method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a protocol conversion module that converts data forms used between a USB 2.0 bus and an IEEE 1394 bus. <P>SOLUTION: The protocol conversion module 100 includes: a USB 20 EPC (End Point Controller) 101 acting like a USB 2.0 interface connected to devices on a USB 2.0 bus; a 1394 LLC (Link Layer Controller) 103 and a 1394 PHY (transceiver / arbiter) 104 acting like IEEE 1394 interface means connected to devices on an IEEE 1394 bus; a 1394 LOGIC 102 acting like a conversion means for converting data forms between the USB 2.0 interface means and the IEEE 1394 interface means; a data RAM 105; and an MCU 106. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a protocol conversion module for converting between a USB 2.0 bus and an IEEE 1394 bus, and a data transfer method.
[0002]
[Prior art]
2. Description of the Related Art In recent years, IEEE 1394 (IEEE Standard for a) has been used as an interface for interconnecting personal computer (hereinafter, referred to as PC), PC peripheral devices such as printers and scanners, digital video discs (hereinafter, referred to as DVD), digital video cameras, and the like. High Performance Serial Bus and USB 1.1 (Universal Serial Bus Revision 1.1) have attracted attention.
[0003]
IEEE 1394 has a maximum transfer rate of 400 megabits per second (Mbps), and USB 1.1 has a maximum transfer rate of 12 megabits per second (Mbps). When viewed from the transfer rate, IEEE 1394 is superior, but USB1. 1 in PCs is ahead of schedule.
[0004]
Recently, USB 2.0 has been standardized with the aim of increasing the speed of USB 1.1, and compatible products have been commercialized. It should be noted that USB 2.0 has a maximum transfer speed of 480 megabits at maximum and is compatible with USB 1.1, so that it is expected that the mounting on a PC will be accelerated in the future. On the other hand, IEEE 1394 is also considered as an interface that handles moving images, and standards such as a digital interface (IEC61883) for audio / video equipment (hereinafter, referred to as AV equipment) using IEEE 1394 have been determined.
[0005]
By the way, in order to transfer data between a device connected to the IEEE 1394 bus and a device connected to the USB bus, it is necessary to mutually convert data formats. Techniques for performing such conversion have been conventionally proposed. Have been. For example, Japanese Patent Application Laid-Open No. H11-145995 proposes a data transmission method for a bus that connects a USB bus and an IEEE 1394 bus that have different resource acquisition methods. In addition, Japanese Patent Application Laid-Open No. 2001-333130 proposes a data transfer system in which DTCP (Digital Transmission Content Protection), which is a standard for unauthorized copy prevention technology of IEEE1394, can be applied to a USB bus.
[0006]
[Problems to be solved by the invention]
However, Japanese Patent Application Laid-Open Nos. 11-145995 and 2001-333130 do not disclose a technique for converting between a USB 2.0 bus and an IEEE 1394 bus, and a protocol conversion module for performing such conversion is conventionally realized. I didn't.
SUMMARY An advantage of some aspects of the invention is to provide a protocol conversion module for performing conversion between a USB 2.0 bus and an IEEE 1394 bus, and a data transfer method.
[0007]
[Means for Solving the Problems]
The protocol conversion module according to the present invention includes a USB 2.0 interface unit connected to a device on a USB 2.0 bus, an IEEE 1394 interface unit connected to a device on an IEEE 1394 bus, the USB 2.0 interface unit and the IEEE 1394 interface. And a conversion means for mutually converting the data format with the means.
Also, the data transfer method of the present invention provides a method for mutually converting data formats between a USB 2.0 interface unit connected to a device on a USB 2.0 bus and an IEEE 1394 interface unit connected to a device on an IEEE 1394 bus. Is performed.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
[First Embodiment]
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing the configuration of the protocol conversion module according to the first embodiment of the present invention. The protocol conversion module 100 according to the present embodiment includes a USB 2.0 endpoint controller (hereinafter referred to as USB20EPC) 101, a device interface / data transfer controller (hereinafter referred to as LOGIC) 102, and an IEEE1394 link layer controller. (Link Layer Controller; hereinafter, referred to as 1394 LLC) 103; IEEE 1394 transceiver / arbiter (hereinafter, referred to as 1394 PHY) 104; data RAM (Random Access Memory; hereinafter, referred to as RAM) 105; Micro Controller Unit, hereafter MCU 106).
[0009]
A USB 20 EPC 101 serving as a USB 2.0 interface means controls a function of an upper layer of USB 2.0 and controls USB 2.0 data transfer (addition / deletion of a USB header, control of an endpoint, and the like). The USB 20 EPC 101 controls the function of a physical layer of USB 2.0, and a transceiver (Transceiver) such as a serial interface engine (hereinafter, referred to as SIE) that transmits and receives data as an electrical interface with a USB 2.0 bus. , Hereinafter referred to as USB20PHY).
[0010]
The LOGIC 102 serves as an interface between the USB 20 EPC 101, the 1394 LLC 103, and the data RAM 105 and the MCU 106, and controls data transfer therebetween.
[0011]
The 1394 LLC 103 and the 1394 PHY 104 serve as IEEE 1394 interface means. The 1394 LLC 103 manages the function of the upper layer of IEEE 1394, and controls the data transfer of IEEE 1394 (addition / deletion of the IEEE 1394 header, control of the IEEE 1394 bus, etc.). The 1394 PHY 104 controls the function of the physical layer of the IEEE 1394, and transmits and receives data as an electrical interface with the IEEE 1394 bus.
[0012]
RAM 105 stores data. The MCU 106 controls the USB 20 EPC 101, the 1394 LLC 103, and the LOGIC 102, and interfaces with devices connected to the USB 2.0 bus or the IEEE 1394 bus. The MCU 106 has firmware (hereinafter, referred to as F / W) stored in an internal ROM (Read Only Memory), not shown, and is operated by the F / W. The LOGIC 102, the data RAM 105, and the MCU 106 serve as conversion means for mutually converting the data format between the USB 2.0 interface means and the IEEE 1394 interface means.
[0013]
Hereinafter, the operation of the protocol conversion module according to the present embodiment will be described with reference to FIG. The example in FIG. 2 shows a case where moving image data is transferred between a PC and a digital video camcorder (hereinafter, referred to as DVC). 2, reference numeral 201 denotes a PC, 202 denotes a USB 2.0 cable, 203 denotes an IEEE 1394 cable, and 204 denotes a DVC.
[0014]
First, when the PC 201 controls the DVC 204, a function control protocol (Function Control Protocol, hereinafter referred to as FCP) command output from the PC 201 to the USB 2.0 cable 202 is transferred to the USB 20 EPC 101 of the protocol conversion module 100.
[0015]
The MCU 106 of the protocol conversion module 100 reads the FCP command from the USB 20 EPC 101 via the LOGIC 102, and writes the FCP command to the 1394 LLC 103 via the LOGIC 102. The FCP command written in the 1394 LLC 103 is output to the IEEE 1394 cable 203 via the 1394 PHY 104 and transferred to the DVC 204. Thus, the DVC 204 can be controlled from the PC 201.
[0016]
Conversely, when a command is transferred from the DVC 204 to the PC 201, the command output from the DVC 204 to the IEEE 1394 cable 203 is transferred to the 1394 PHY 104 of the protocol conversion module 100 and transferred to the 1394 LLC 103. The MCU 106 reads a command from the 1394 LLC 103 via the LOGIC 102 and writes the command to the USB 20 EPC 101 via the LOGIC 102. The command written in the USB20 EPC 101 is output to the USB 2.0 cable 202 and transferred to the PC 201.
[0017]
Next, when the moving image data is transferred from the DVC 204 to the PC 201, the moving image data output by the DVC 204 in response to the FCP command from the AP on the PC 201 is input to the protocol conversion module 100 via the IEEE 1394 cable 203. The moving image data passes through the 1394 PHY 104 and the 1394 LLC 103 and is stored in the RAM 105 via the LOGIC 102.
[0018]
The MCU 106 writes the moving image data stored in the RAM 105 to the USB 20 EPC 101 via the LOGIC 102. The moving image data written in the USB20 EPC 101 is output to the USB 2.0 cable 202 and transferred to the PC 201.
[0019]
Conversely, when transferring moving image data from the PC 201 to the DVC 204, moving image data output from the PC 201 to the USB 2.0 cable 202 is transferred to the USB 20 EPC 101 of the protocol conversion module 100 and stored in the RAM 105 via the LOGIC 102. The MCU 106 writes the moving image data stored in the RAM 105 to the 1394 LLC 103 via the LOGIC 102. The moving image data written to the 1394 LLC 103 is output to the IEEE 1394 cable 203 via the 1394 PHY 104 and transferred to the DVC 204.
[0020]
When application software (hereinafter, referred to as AP) on the PC 201 controls the DVC 204, a driver for controlling the DVC 204 connected to the IEEE 1394 bus (hereinafter, IEEE 1394) together with a USB driver corresponding to the USB 2.0 bus. It is necessary to incorporate a conversion driver serving as an interface between the USB driver and the IEEE 1394 driver into the PC 201.
[0021]
In the PC 201, commands and moving image data are transferred from the USB driver to the IEEE 1394 driver via the conversion driver, and the commands and moving image data are transferred to the AP. Also, commands and moving image data from the AP are transferred from the IEEE 1394 driver to the USB driver via the conversion driver.
[0022]
[Second embodiment]
In the first embodiment, the 1394 LLC 103 and the 1394 PHY 104 are separately provided, but the 1394 LLC 103 may include the 1394 PHY 104. Also, in the first embodiment, the USB20EPC101 includes the USB20PHY, but the USB20PHY may be provided separately from the USB20EPC101. Further, in the first embodiment, the LOGIC 102 and the RAM 105 are separately provided, but the LOGIC 102 may include the RAM 105. Further, in the first embodiment, the MCU 106 stores the F / W in the internal ROM, but the F / W may be stored in the external ROM.
[0023]
Further, in the first embodiment, the data transfer is performed via the RAM 105, but the data transfer may not be performed via the RAM 105. In the first embodiment, data transfer is performed via the LOGIC 102. However, the MCU 106 may directly transfer data to the USB 20 EPC 101 or the 1394 LLC 103 without using the LOGIC 102. In the first embodiment, DVC is described as an example of the IEEE 1394 device connected to the IEEE 1394 bus. However, by replacing the driver used in the PC 201 with another driver (for example, a hard disk driver), another driver can be used. It is also possible to execute the application of the IEEE 1394 device. Further, the protocol conversion module 100 according to the first embodiment may be realized by one chip, or may be realized by two or more chips.
[0024]
【The invention's effect】
According to the present invention, a USB 2.0 interface connected to a device on a USB 2.0 bus, an IEEE 1394 interface connected to a device on an IEEE 1394 bus, and a connection between the USB 2.0 interface and the IEEE 1394 interface. And a conversion means for mutually converting data formats, a USB 2.0-to-IEEE 1394 conversion module can be realized, and an application using data transfer between the USB 2.0 bus and the IEEE 1394 bus is realized. be able to.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of a protocol conversion module according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing a configuration in which a personal computer and a digital video camcorder are connected using the protocol conversion module of FIG. 1;
[Explanation of symbols]
101 USB20 EPC, 102 LOGIC, 103 1394 LLC, 104 1394PHY, 105 RAM, 106 MCU.

Claims (2)

USB 2.0 interface means connected to a device on a USB 2.0 bus;
IEEE 1394 interface means connected to devices on the IEEE 1394 bus;
A protocol conversion module comprising conversion means for mutually converting data formats between the USB 2.0 interface means and the IEEE 1394 interface means. Executing a data conversion procedure for mutually converting a data format between a USB 2.0 interface unit connected to a device on a USB 2.0 bus and an IEEE 1394 interface unit connected to a device on an IEEE 1394 bus. Characteristic data transfer method.

Images