1. Field of the Invention
The present invention relates to an image transmission apparatus for distributing images using an IP network (IP image transmission apparatus), and more particularly to a data bus system which is required to realize a live distribution function (UDP transmission) and a server storage function (TCP transmission).
2. Description of the Related Art
IP image transmission apparatus transmit image and encoded audio data by way of UDP transmission for live distribution and store image and encoded audio data by way of TCP transmission in a server.
According to a live distribution function, data are transmitted in real time according to the UDP with no retransmission process in order to perform the real-time, low-delay live distribution function on an IP network. For transmitting live distribution data, encoded data according to various encoding processes need to be transmitted at transmission rates equal to or higher than a certain transmission rate. Specifically, for realizing real-time transmission at a certain transmission rate, it is necessary to finish the transmission process within a certain time. A minimum unit of such a certain time is a time required to transmit a single UDP packet (live distribution minimum unit time). The live distribution minimum unit time Tlive is expressed by the following equation (1):
Tlive=(encoding rate [bps])/(8×UDP packet size [byte]) (1)
The encoding rate refers to a bit rate for encoding image and audio data. In order for a server storage function to store data free of frame losses in a server, storage data are transmitted with reliability according to the TCP with a retransmission process. Therefore, it is a minimum requirement to finish both the live distribution function and the server storage function within the live distribution minimum unit time for simultaneously realizing the live distribution function and the server storage function on the IP network.
(1) Encoded Data Transfer:
The encoding LSI control process 72 transfers encoded data to the memory 58 through the CPU bus 66. The encoded data are generated by the image/audio data encoding device 54 from digital video data converted from analog video data by the video A/D converter 50 and digital audio data converted from analog audio data by the audio A/D converter 52.
(2) Encoded Data Reading:
The IP packet processing process 76 reads the encoded data from the memory 58 through the CPU bus 66.
(3) UDP Packetized Data Writing:
The IP packet processing process 76 converts the encoded data into UDP packets, and writes them into the memory 58 through the CPU bus 66.
(4) UDP Data Sending:
The network transmitting process 78 reads the UDP packets from the memory 58 through the CPU bus 66, and transmits the UDP packets through the network control device 62 and the network I/F 64 to the IP network according to the UDP.
(5) Storage Data Writing:
The storage control process 74 reads the encoded data from the memory 58 through the CPU bus 66, and transfers the encoded data to the storage medium 56.
(6) Storage Data Reading:
The storage control process 74 reads the encoded data from the storage medium 56 through the CPU bus 66, and transfers the encoded data to the memory 58.
(7) Encoded Data Reading:
The IP packet processing process 76 reads the encoded data (storage data) from the memory 58 through the CPU bus 66.
(8) TCP Packetized Data Writing:
The IP packet processing process 76 converts the storage data into TCP packets, and write them into the memory 58 through the CPU bus 66.
(9) TCP Data Sending:
The network transmitting process 78 reads the TCP packets from the memory 58 through the CPU bus 66, and transmits the TCP packets through the network control device 62 and the network I/F 64 to the IP network according to the TCP.
There are needs for an increased encoding rate for increasing the quality of images and sounds for live distribution. The encoding rate shown in
Using a high-speed bus results in a need for a high-speed CPU, increasing the power consumption and reducing a design margin. Consequently, a lot of resources are consumed in all aspects, e.g., in the form of a high cost, an increased development cost, etc. If a high-speed storage medium is employed, then a cost increase occurs, and an increase in the mounting area is caused. As a result, the apparatus fails to meet requirements for environment resistance, low power consumption, smaller size, etc.
It is an object of the present invention to provide an IP image transmission apparatus which is capable of meeting requirements for environment resistance, low power consumption, smaller size, etc. and increasing an encoding rate.
According to an aspect of the present invention, there is provided an IP image transmission apparatus for TCP and UDP transmission of encoded data, including a storage medium, a first memory, a first bus, a second bus, an encoder for encoding image and audio data into encoded data and outputting the encoded data to the first bus, an encoded data transfer unit for writing the encoded data output to the first bus into the first memory through the second bus, a storage data writing controller for writing the encoded data output to the first bus into the storage medium through the first bus, and a storage data reading controller for reading storage data written in the storage medium through the first bus and writing the storage data into the first memory through the second bus.
Preferably, the IP image transmission apparatus further includes a second memory, and the encoded data transfer unit writes the encoded data output to the first bus into the second memory, reads the encoded data from the second memory, and writes the encoded data into the first memory through the second bus.
Further preferably, the storage data reading controller writes the storage data read through the first bus into the second memory, reads the encoded data from the second memory, and writes the encoded data into the first memory through the second bus.
The above and other objects, features and advantages of the present invention and the manner of realizing them will become more apparent, and the invention itself will best be understood from a study of the following description and appended claims with reference to the attached drawings showing some preferred embodiments of the invention.
Prior to the description of an embodiment of the present invention, the principles of the present invention will first be described below.
The storage data writing controller 112 writes the encoded data output to the first bus 104 into the storage medium 100 through the first bus 104, as indicated by (6). At this time, since the storage data are written into the storage medium 100 through the first bus 104, but not through the second bus 106, the process of transferring the encoded data to the first memory 102 through the second bus 106 with the encoded data transfer unit 110, and the process of storing the encoded data into the storage medium 100 with the storage data writing controller 112 can be performed parallel to each other.
The storage data reading controller 114 reads the storage data from the storage medium 100 through the first bus 104, and writes the storage data into the first memory 104 through the second bus 106. At this time, since the storage bus is read from the storage medium 100 through the first bus 104, the first memory 102 can be accessed through the second bus 106 and the storage data can be written thereinto while the storage data are being read through the first bus 104, so that the processing time can be shortened.
The video A/D converter 150 converts an analog image captured by a video camera installed outdoors or the like into a digital image. The audio A/D converter 152 converts an analog audio signal recorded by a microphone into a digital audio signal. The image/audio data encoding device 154 has the following functions: (1) It encodes digital image and audio data according to the MPEG-2 process, and stores the encoded data in a frame memory, not shown. (2) It reads the encoded data from the frame memory according to an instruction from an encoding LSI control process 192 in the main CPU 156 through the dedicated DMAC 158, and outputs the encoded data to the dedicated bus 170.
The main CPU 190 is a CPU for controlling and processing data for IP image transmission, and performs a real-time OS 190, an encoding LSI control process 192, a storage control process 194, an IP packet processing process 196, a network transmitting process 198, an http server processing process 200, and an overall apparatus control process 202. The real-time OS 190 is an operating system for switching between the processes at a high speed for real-time distribution. The encoding LSI control process 192 instructs the dedicated DMAC 158 to transfer the encoded data generated by the image/audio data encoding device 154 to the main memory 168. The storage control process 194 has the following functions: (1) Instructing the dedicated DMAC 158 to store the encoded data in the storage medium 162. (2) Instructing the dedicated DMAC 158 to read the storage data from the storage medium 162 to the memory 160.
The IP packet processing process 196 performs the following processes: (1) Reading the encoded data from the memory 160 to the main CPU 156 through the CPU bus 168. (2) Converting the encoded data read from the memory 160 into UDP packets. (3) Writing the UDP packets into the memory 160 through the CPU bus 168. (4) Reading the storage data from the memory 160 to the main CPU 156 through the CPU bus 168. (5) Converting the storage data read from the memory 160 into TCP packets. (6) Writing the TCP packets into the memory 160.
The network transmitting process 198 performs the following processes: (1) Transferring the UDP packets from the memory 160 to the network control device 164 through the CPU bus 168. (2) Transferring the TCP packets from the memory 160 to the network control device 164 through the CPU bus 168. The http server processing process 200 performs the following processes: (1) Setting an IP address of its own apparatus according to an instruction from a server apparatus. (2) Setting an encoding rate (encoding process) according to an instruction from the server.
The overall apparatus control process 202 has the following functions: (1) Controlling a processing sequence of the encoding LSI control process 192, etc. described later on in order to finish the UDP distribution process, the TCP transmission process, and other processes within the live distribution minimum unit time. (2) Performing a monitoring control process in the apparatus, such as an alarm monitoring process.
The dedicated DMAC 158 has a transfer memory 180, and performs the following processes according to instructions sent from the main CPU 156 through a signal line, not shown: (1) When the dedicated bus 170 is idling, the dedicated DMAC 158 reads necessary encoded data from the image/audio data encoding device 154 to the dedicated bus 170, stores the encoded data in a register, and writes the encoded data into the transfer memory 180 within a unit time. When a certain amount of encoded data is written into the transfer memory 180, the dedicated DMAC 158 reads the encoded data from the transfer memory 180, and writes the encoded data into the main memory 160 through the CPU bus 168. (2) The dedicated DMAC 158 acquires the dedicated bus 170, outputs the encoded data written in the register to the dedicated bus 170 in order to write the encoded data through the output into the storage medium 162, and releases the dedicated bus 170 after the bus cycle. When the writing of the encoded data into the storage medium 162 is over, the dedicated DMAC 158 acquires the dedicated bus 170, outputs next encoded data written in the register to the dedicated bus 170 in order to write the encoded data through the output into the storage medium 162, and releases the dedicated bus 170 after the bus cycle. This process is performed on necessary encoded data in the unit time. (3) The dedicated DMAC 158 reads the storage data written in the storage medium 162 to the transfer memory 180 through the dedicated bus 170. When a certain amount of storage data is read to the transfer memory 180, the dedicated DMAC 158 reads the storage data from the transfer memory 180, and writes the storage data into the main memory 160 through the CPU bus 168. (4) The dedicated DMAC 158 acquires the CPU bus 168 according to a request from the CPU 156.
The transfer memory 180 is a buffer memory. The transfer memory 180 is used for the following reasons: (1) There is a difference between the rate to transfer the encoded data from the image/audio data encoding device 154 through the dedicated bus 170 and the transfer rate of the CPU bus 168. (2) The timing to transfer the encoded data to the memory 160 is controlled. (3) There is a difference between the rate to read the storage data from the storage medium 162 through the dedicated bus 170 and the transfer rate of the CPU bus 168. (4) The timing to write the storage data into the memory 160 is controlled.
The memory 160 is a main memory for storing encoded data and processes and includes a ROM for storing a program corresponding to the encoding LSI control process 192, etc. The storage medium 162 is a recording medium for storing encoded data to be sent for TCP transmission, and has a controller. The controller writes the encoded data on the dedicated bus 170 into the storage medium 162, and reads the storage data from the storage medium 162 to the dedicated bus 170. The network control device 164 serves to interface a network to which the IP image transmission apparatus is connected. The network I/F 166 includes connectors, transformers, etc. for connecting the IP image transmission apparatus to communication cables.
The CPU bus 168 is a bus for writing and reading encoded data between the main CPU 156 and the memory 160, encoded data between the dedicated DMAC 158 and the memory 160, UDP packets, storage data, and TCP packets. The dedicated bus 170 serves to write encoded data into the storage medium 162, read encoded data from the storage medium 162, and read encoded data from the image/audio data encoding device 154.
The network control device 164 includes a LAN controller, for example. The DMAC182#1 is an encoded data LSI control DMAC and performs the following processes according to instructions from the encoding LSI control process 192: (1) When the dedicated bus 170 is idling, it reads encoded data from the image/audio data encoding device 154 to the dedicated bus 170, and writes the encoded data into the register. (2) It writes the encoded data written in the register into the transfer memory 180.
The DMAC182#2 is a storage control DMAC and performs the following processes according to instructions from the storage control process 194: (1) It acquires the dedicated bus 170, and sends a request to write necessary encoded data written in the register through the dedicated bus 170 to the storage medium 162, and releases the dedicated bus 170 after the bus cycle within a unit time. (2) It acquires the dedicated bus 170, reads the storage data from the storage medium 162 through the dedicated bus 170, and writes the storage data into the transfer memory 180.
The DMAC182#3 is a memory controller DMAC and performs the following processes: (1) When a certain amount of encoded data/storage data is written in the transfer memory 180, the DMAC182#3 write the data into the memory 160 through the CPU bus 168. (2) The DMAC182#3 acquires the CPU bus 168 according to an instruction from the IP packet processing process 196 or the network transmitting process 198.
The transfer memory 180 includes a dual-port memory, for example, because encoded data may simultaneously be written in and read from the transfer memory 180. The storage medium 162 includes an ATAHDD card having a transfer rate of about 22 Mbps to meet requirements for small size and light weight, and has a controller. The CPU bus 168 has a bus width of 32 bits and a maximum transfer rate of 324 Mbytes/second, for example.
(1) Encoded Data Transfer:
The image/audio data encoding device 154 encodes audio and image data according to the MPEG-2 process, and stores the encoded data in a frame memory. At the beginning of the unit time shown in
When a bus cycle for storage data writing (5), described later, is finished, releasing the dedicated bus 170, the DMAC182#1 reads next encoded data from the image/audio data encoding device 154 to the dedicated bus 170, and writes the encoded data into the register. The encoded data transfer (1a) from the image/audio data encoding device 154 is performed on encoded data required for UDP packetization. The DMAC182#1 writes the encoded data written in the register into the transfer memory 180, as indicated by (1) in
(2) Encoded Data Reading:
When the encoded data transfer (1b) to the memory 160 shown in
(3) UDP Packetized Data Writing:
The IP packet processing process 196 converts the encoded data read from the memory 160 into UDP packets, and writes the UDP packets into the memory 160 through the CPU bus 168, as indicated by (3).
(4) UDP Packet Data Sending:
When the UDP packetized data writing (3) is finished, the overall apparatus control process 202 activates the network transmitting process 198. The network transmitting process 198 reads the UDP packets from the memory 160 through the CPU bus 168, and outputs the UDP packets to the network control device 164 as indicated by (4) in
(5) Storage Data Writing:
When the encoded data are written into the register by the encoded data transfer (1a) shown in
The controller of the storage medium 162 receives the encoded data from the dedicated bus 170, and stores the encoded data in the storage medium 162 as indicated by (5) in
(6a) Storage Data Reading:
When the storage data writing (5) is over, the overall apparatus control process 202 activates the storage control process 194. The storage control process 194 instructs the storage control DMAC182#2 to read corresponding encoded data from the storage medium 162. The DMAC182#2 successively reads the storage data from the storage medium 162 to the dedicated bus 170 through the controller of the storage medium 162, and writes the storage data into the transfer memory 180. At this time, the storage data reading (6a) is performed by the DMAC182#2 through the dedicated bus 170. The UDP data sending (4) and the other processes (10) including the process of communication with the server and the overall apparatus control sequence are carried out by the CPU 156 through the CPU bus 168. Therefore, the process (6a), and the process (4) and the other processes (10) can be performed parallel to each other.
(6b) Storage Data Reading:
When the storage data are written in the transfer memory 180, the DMAC182#3 reads the storage data from the transfer memory 180 and writes the storage data into the memory 160 through the CPU bus 168 parallel to the process (6a), as indicated by (6) in
(7) Encoded Data Reading:
When the storage data reading (6b) shown in
(8) TCP Packet Data Writing:
The IP packet processing process 196 receives the storage data read to the CPU bus 168 and converts the storage data into TCP packets as indicated by (8) in
(9) TCP Data Sending:
When the TCP data writing (8) shown in
(10) Other Processes:
During an idling time between the UDP packet process and the TCP packet process, e.g., when the UDP data sending (4) is finished, the overall apparatus control process 202 performs overall apparatus control sequences including the process of communication with the server and the overall apparatus control sequence between the CPU 156 and the memory 160, as indicated by (10) in
As shown in
According to the present invention, as described above, a dedicated bus is provided to allow UDP and TCP processes based on accessing a memory through a CPU bus and processes for writing data into and reading data from a storage medium through the dedicated bus to be performed parallel to each other. An encoded data transferring time can be shortened for an increased encoding rate even if the transfer rates of the storage medium and the CPU bus are not increased.
The present invention is not limited to the details of the above described preferred embodiments. The scope of the invention is defined by the appended claims and all changes and modifications as fall within the equivalence of the scope of the claims are therefore to be embraced by the invention.
This is a continuation of PCT International Application NO. PCT/JP03/04854, filed Apr. 16, 2003, which was not published in English, currently pending, the contents of which are herein wholly incorporated by reference.
Number | Name | Date | Kind |
---|---|---|---|
5506957 | Fry et al. | Apr 1996 | A |
5691948 | Sakabe | Nov 1997 | A |
5862437 | Kutsuwada et al. | Jan 1999 | A |
6449732 | Rasmussen et al. | Sep 2002 | B1 |
Number | Date | Country |
---|---|---|
11-112934 | Apr 1999 | JP |
2000-236403 | Aug 2000 | JP |
2001-268516 | Sep 2001 | JP |
2003-018525 | Jan 2003 | JP |
2003-061022 | Feb 2003 | JP |
WO0043868 | Jul 2000 | WO |
Number | Date | Country | |
---|---|---|---|
20050175036 A1 | Aug 2005 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/JP03/04854 | Apr 2003 | US |
Child | 11105914 | US |