US20030165330A1

US20030165330A1 - Optical disc player system and method of controlling a decoding unit in the optical disc player system to read encoded bitstream data from a buffer memory

Info

Publication number: US20030165330A1
Application number: US10/376,443
Authority: US
Inventors: Shang-Tzu Ju
Original assignee: MediaTek Inc
Current assignee: MediaTek Inc
Priority date: 2002-03-01
Filing date: 2003-02-28
Publication date: 2003-09-04
Also published as: US20090232482A1; US20120301118A1; TW591611B; US8254765B2; US20060165390A1; US7555201B2

Abstract

In a method of controlling multiple decoders in an optical disc player system to read encoded bitstream data divided into multiple sectors from a buffer memory, one of the sectors stored in the buffer memory is read according to a reading pointer associated with one of the decoders that sent out a bitstream request. When a header portion of the sector that is being read from the buffer memory indicates a bitstream type corresponding to that of the bitstream request, a data portion of the sector is transferred to the decoder that sent out the bitstream request, and the reading pointer is adjusted to point to a next one of the sectors stored in the buffer memory. An optical disc player system for implementing the method is also disclosed.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a system and method for controlling a decoding unit to read data from a memory device, more particularly to an optical disc player system and method of controlling a decoding unit in the optical disc player system to read encoded bitstream data from a buffer memory.

2. Description of the Related Art

FIG. 1 illustrates a conventional

DVD player system

1 that includes a channel decoder 11 for reading and error-correcting the encoded bitstream data from a disc, a track buffer 13 connected to the channel decoder 11 via a memory interface 15 for storing error-corrected bitstream data from the channel decoder 11, a source decoder 12 connected to the channel decoder 11 for decoding the bitstream data from the channel decoder 11, and a source buffer 14 connected to the source decoder 12 via a memory interface 16 for storing decoded video and audio data from the source decoder 12. In an actual design, the channel decoder 11 and the source decoder 12 are implemented using two separate chips, thereby resulting in a relatively high cost. In order to reduce costs, there is provided a combined chip integrated with the aforesaid functions of the channel and source decoders.

FIG. 2 illustrates another

DVD player system

2 that includes a decoding unit 21 having a channel decoder 11′ and a source decoder 12′. The integrated decoding unit 21 performs functions the same as those in the system of FIG. 1, and a combined buffer memory 22 connected to the decoding unit 21 via a memory interface 23. Referring to FIG. 3, the buffer memory 22 includes a track buffer 221 for storing data from a disc, and a bitstream buffer 222 for storing demultiplexed bitstream data processed by a bitstream demultiplexer 24 and decoded video and audio data for playback. The decoding unit 12′ includes an audio decoder, a video decoder, a sub-picture decoder 123 and a navigation decoder 124. During a decoding procedure, the bitstream demultiplexer 24 reads encoded bitstream data from the track buffer 221 of the buffer memory 221 via the memory interface 23. After error-correcting and demultiplexing of the encoded bitstream data, the demultiplexed bitstream data is transferred to the bitstream buffer 222 of the buffer memory 22 via the memory interface 23. The decoders 121, 122, 123, 124 read the demultiplexed bitstream data stored in the bitstream buffer 222 of the buffer memory 22 for decoding via the memory interface 23. As such, the buffer memory 22 in the conventional system 2 of FIG. 2 must provide a large bandwidth for channel decoding and source decoding, thereby resulting in relatively high costs and power consumption.

SUMMARY OF THE INVENTION

Therefore, the object of the present invention is to provide an optical disc player system and method of controlling a decoding unit in the optical disc player system to read encoded bitstream data from a buffer memory that can reduce the memory bandwidth requirement so as to result in relatively low costs and power consumption.

According to one aspect of the present invention, there is provided a method of controlling a decoding unit in an optical disc player system to read encoded bitstream data from a buffer memory. The encoded bitstream data is divided into a plurality of sectors, each of which includes a data portion, and a header portion for indicating a bitstream type of the data portion. The decoding unit includes a set of different decoders, each of which is used to decode data with a specific bitstream type. The method comprises the steps of:

(a) determining whether one of the decoders sent out a bitstream request;

(b) reading one of the sectors stored in the buffer memory according to a reading pointer that is associated with said one of the decoders that sent out the bitstream request;

(c) determining whether a portion of said one of the sectors being read from the buffer memory is the header portion;

(d) determining whether the header portion of said one of the sectors that is being read from the buffer memory indicates a bitstream type corresponding to that of the bitstream request upon determining that the portion of said one of the sectors is the header portion; and

(e) transferring the data portion of said one of the sectors that is being read from the buffer memory to said one of the decoders that sent out the bitstream request upon determining that the bitstream type indicated by the header portion of said one of the sectors corresponds to that of the bitstream request, and adjusting the reading pointer to point to a next one of the sectors stored in the buffer memory after reading of said one of the sectors has been completed.

According to another aspect of the present invention, an optical disc player system comprises:

a buffer memory for storing encoded bitstream data, the encoded bitstream data being divided into a plurality of sectors, each of which includes a data portion, and a header portion for indicating a bitstream type of the data portion;

a header scanning controller connected to the buffer memory;

a decoding unit connected to the header scanning controller, the decoding unit including a set of different decoders, each of which is used to decode data with a specific bitstream type, each of the decoders being capable of sending a bitstream request for reading encoded bitstream data stored in the buffer memory to the header scanning controller; and

a reading pointer recorder connected to the header scanning controller and storing a plurality of reading pointers associated with the decoders;

the header scanning controller reading one of the sectors stored in the buffer memory according to the reading pointer from the reading pointer recorder that is associated with one of the decoders that sent out the bitstream request when the header scanning controller receives the bitstream request from said one of the decoders;

the header scanning controller transferring the data portion of said one of the sectors that is being read from the buffer memory to said one of the decoders that sent out the bitstream request when the header portion of said one of the sectors that is being read from the buffer memory indicates a bitstream type corresponding to that of the bitstream request, and enabling the reading pointer recorder to adjust the reading pointer to point to a next one of the sectors stored in the buffer memory after reading of said one of the sectors has been completed.

BRIEF DESCRIPTION OF THE DRAWINGS

Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiment with reference to the accompanying drawings, of which: [0020]
FIG. 1 is a schematic circuit block diagram of a conventional DVD player system; [0021]
FIG. 2 is a schematic circuit block diagram of another conventional DVD player system; [0022]
FIG. 3 is a schematic circuit block diagram illustrating a bitstream demultiplexing operation in the conventional DVD player system of FIG. 2; [0023]
FIG. 4 is a schematic circuit block illustrating the preferred embodiment of an optical disc player system according to the present invention; and [0024]
FIG. 5 is a flow chart illustrating a method of controlling a decoding unit in the preferred embodiment to read encoded bitstream data from a buffer memory.[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to FIG. 4, the preferred embodiment of an optical disc player system [0026] 3, such as a DVD player, according to the present invention is shown to include a buffer memory 33, a header scanning controller 34, a decoding unit 32, and a reading pointer recorder 35.
The [0027] buffer memory 33, such as a track buffer, stores encoded bitstream data that is read by a disc reading module 31 from an optical disc (not shown) and that is error-corrected by a channel decoder 30. The encoded bitstream data is divided into a plurality of sectors, each of which includes a data portion, and a header portion for indicating a bitstream type of the data portion. The header portion includes a sector ID, a pack header and a packet header.
The [0028] header scanning controller 34 is connected to the buffer memory 33 via a memory interface 36.
The decoding unit [0029] 32 is connected to the header scanning controller 34, and includes a channel decoder 321 and a set of different data decoders including audio decoder 322A, video decoder 322B, sub-picture decoder 322C, and navigation decoder 322D. Each of the data decoder is used to decode data with a specific bitstream type. Each of the data decoders 322A, 322B, 322C, 322D is capable of sending a bitstream request for reading encoded bitstream data stored in the buffer memory 33 via the header scanning controller 34. In this embodiment, the decoding unit 32 includes an audio decoder 322A for decoding audio data, a video decoder 322B for decoding video data, a sub-picture decoder 322C, and a navigation decoder 322D.
The [0030] reading pointer recorder 35 is connected to the header scanning controller 34 and stores four reading pointers associated with the data decoders 322A, 322B, 322C, and 322D. The four reading pointers are audio reading pointer, video reading pointer, sub-picture reading pointer, and navigation reading pointer respectively.
The [0031] header scanning controller 34 reads one of the sectors stored in the buffer memory 33 according to the reading pointer from the reading pointer recorder 35 that is associated with one of the decoders 322A, 322B, 322C, 322D that sent out the bitstream request when the header scanning controller 34 receives the bitstream request from said one of the data decoders 322A, 322B, 322C, 322D.
The [0032] header scanning controller 34 transfers the data portion of said one of the sectors that is being read from the buffer memory 33 to the data decoder (322A, 322B, 322C, or 322D) that sent out the bitstream request when the header portion of said one of the sectors that is being read from the buffer memory 33 indicates a bitstream type corresponding to that of the bitstream request, and the header scanning controller 34 also enables the reading pointer recorder 35 to adjust the reading pointer to point to a next one of the sectors stored in the buffer memory 33 after reading of said one of the sectors has been completed.
Furthermore, the [0033] header scanning controller 34 enables the reading pointer recorder 35 to adjust the reading pointer associated with said one of the decoders 322A, 322B, 322C, 322D that sent out the bitstream request to point to a next one of the sectors stored in the buffer memory 33, and reads the header portion of the next one of the sectors when the bitstream type indicated by the header portion of said one of the sectors being read from the buffer memory 33 does not correspond to that of the bitstream request.
For example, when the [0034] video decoder 322B sends out a bitstream request for video data, the header scanning controller 34 receives the bitstream request, reads the sector which is a video bitstream type (a video sector) according to the video reading pointer of the reading pointer recorder 35. After the current video sector has been read from the buffer memory 33, the header scanning controller 34 enables the reading pointer recorder 35 to move the video reading pointer to a next video sector in the buffer memory 33. The similar procedure also applies to the audio decoder 322A, the sub-picture decoder 322C, and the navigation decoder 322D.
It is noted that each of the sectors stored in the [0035] buffer memory 33 is defined by the header scanning controller 34 to be in a used state when the data portion thereof has been completely read, and to be in an unused state when otherwise. The header scanning controller 34 enables the reading pointer recorder 35 to adjust the four reading pointers to point the next audio sector, next video sector, next sub-picture sector, or next 34 enables the reading pointer recorder 35 to adjust the four reading pointers to point the next audio sector, next video sector, next sub-picture sector, or next navigation sector in the buffer memory 33 that is in the unused state when the bitstream type indicated by the header portion of said one of the sectors being read from the buffer memory 33 does not correspond to that of the current bitstream request.
Referring to FIG. 5, there is shown a flow chart to illustrate how the [0036] header scanning controller 34 controls the decoding unit 32 in the optical disc player system 3 of the preferred embodiment to read the bitstream data from the buffer memory 33. In step 41, the header scanning controller 34 determines whether one of the decoders 322A, 322B, 322C, 322D sends out the bitstream request. For example, the header scanning controller 34 detects that the audio decoder 321 sends out the bitstream request for decoding audio data. In step 42, the header scanning controller 34 reads one of the sectors stored in the buffer memory 33 according to a reading pointer that is associated with said one of the decoders 322A, 322B, 322C, 322D that sends out the bitstream request (for example, the audio decoder 322A). In step 43, the header scanning controller 34 determines whether a portion of said one of the sectors being read from the buffer memory 33 is the header portion. In step 45, when the portion of said one of the sectors 33 indicates a bitstream type corresponding to that of the bitstream request. In step 46, the header scanning controller 34 transfers the data portion of said one of the sectors that is being read from the buffer memory 33 to said one of the decoders 322A, 322B, 322C, 322D that sends out the bitstream request (for example, the audio decoder 322A) upon determining in step 45 that the bitstream type indicated by the header portion of said one of the sectors corresponds to that of the bitstream request, and enables the reading pointer recorder 35 to adjust the reading pointer to point to a next one of the sectors stored in the buffer memory 33 after reading of said one of the sectors has been completed. It is noted that, in this case, the reading pointer recorder 35 adjusts the reading pointer to point to the next one of the sectors stored in the buffer memory 33 that is in the unused state. Furthermore, when it is determined in step 43 that the portion of said one of the sectors being read from the buffer memory 33 is not the header portion, the flow proceeds to step 46. In step 47, the header scanning controller 34 determines whether the data portion of said one of the sectors that is being read from the buffer memory 33 has been read completely. When the data portion of said one of the sectors that is being read from the buffer memory 33 has yet to be read completely, the flow proceeds back to step 41. In step 48, the header scanning controller 34 defines said one of the sectors to be in the used state when the data portion of said one of the sectors that is being read from the buffer memory 33 has been read completely, and the flow proceeds back to step 41. In step 49, the header scanning controller 34 enables the reading pointer recorder 35 to adjust the reading pointer associated with said one of the decoders 322A, 322B, 322C, 322D (for example, the audio decoder 322A) that sends out the bitstream request to point to the next one of the sectors stored in the buffer memory 33, and reads the header portion of the next one of the sectors when the bitstream type indicated by the header portion of said one of the sectors being read from the buffer memory 13 is determined in step 45 as not corresponding to that of the bitstream request. The flow then proceeds back to step 45. It is noted that, in this case, the reading pointer recorder 35 adjusts the reading pointer to point to the next one of the sectors stored in the buffer memory 33 that is in the unused state. In step 44, when none of the decoders 321, 322, 323, 324 sent out a bitstream request, the header scanning controller. 34 determines whether decoding of the decoding unit 32 ends. If no, the flow proceeds back to step 41.
Accordingly, in the optical disc player system [0037] 3 of the present invention, the header scanning controller 34 can control the decoding unit 32 to read encoded bitstream data from the buffer memory 33 through the memory interface 36 such that the buffer memory 33 has a relatively low memory bandwidth requirement, thereby resulting in relatively low costs and power consumption. The object of the invention is thus met.
While the present invention has been described in connection with what is considered the most practical and preferred embodiment, it is understood that this invention is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretation so as to encompass all such modifications and equivalent arrangements. [0038]

Claims

I claim:

1. A method of controlling a decoding unit in an optical disc player system to read encoded bitstream data from a buffer memory, the encoded bitstream data being divided into a plurality of sectors, each of which includes a data portion, and a header portion for indicating a bitstream type of the data portion, the decoding unit including a set of different decoders, each of which is used to decode data with a specific bitstream type, said method comprising the steps of:

(a) determining whether one of the decoders sent out a bitstream request;

2. The method as claimed in claim 1, wherein the decoders include at least one of a video decoder for decoding video data, an audio decoder for decoding audio data, a sub-picture decoder, and a navigation decoder.

3. The method as claimed in claim 1, wherein the header portion includes a sector ID, a pack header and a packet header.

4. The method as claimed in claim 1, further comprising the step of:

(f) upon determining that the bitstream type indicated by the header portion of said one of the sectors being read from the buffer memory does not correspond to that of the bitstream request, adjusting the reading pointer to point to the next one of the sectors stored in the buffer memory, reading the header portion of the next one of the sectors, and proceeding back to step (d).

5. The method as claimed in claim 4, wherein each of the sectors stored in the buffer memory is defined to be in a used state when the data portion thereof has been completely read, and is defined to be in an unused state when otherwise.

6. The method as claimed in claim 5, wherein, in step (f), the reading pointer is adjusted to point to the next one of the sectors stored in the buffer memory that is in the unused state.

7. An optical disc player system, comprising:

a header scanning controller connected to said buffer memory;

a decoding unit connected to said header scanning controller, said decoding unit including a set of different decoders, each of which is used to decode data with a specific bitstream type, each of said decoders being capable of sending a bitstream request for reading encoded bitstream data stored in said buffer memory to said header scanning controller; and

a reading pointer recorder connected to said header scanning controller and storing a plurality of reading pointers associated with said decoders;

said header scanning controller reading one of the sectors stored in said buffer memory according to the reading pointer from said reading pointer recorder that is associated with one of said decoders that sent out the bitstream request when said header scanning controller receives the bitstream request from said one of said decoders;

said header scanning controller transferring the data portion of said one of the sectors that is being read from said buffer memory to said one of the decoders that sent out the bitstream request when the header portion of said one of the sectors that is being read from said buffer memory indicates a bitstream type corresponding to that of the bitstream request, and enabling said reading pointer recorder to adjust the reading pointer to point to a next one of the sectors stored in said buffer memory after reading of said one of the sectors has been completed.

8. The optical disc player system as claimed in claim 7, wherein said decoders include at least one of a video decoder for decoding video data, an audio decoder for decoding audio data, a sub-picture decoder, and a navigation decoder.

9. The optical disc player system as claimed in claim 7, wherein the header portion includes a sector ID, a pack header and a packet header.

10. The optical disc player system as claimed in claim 7, wherein said header scanning controller enables said reading pointer recorder to adjust the reading pointer associated with said one of said decoders that sent out the bitstream request to point to a next one of the sectors stored in said buffer memory, and reads the header portion of the next one of the sectors when the bitstream type indicated by the header portion of said one of the sectors being read from said buffer memory does not correspond to that of the bitstream request.

11. The optical disc player system as claimed in claim 10, wherein each of the sectors stored in said buffer memory is defined by said header scanning controller to be in a used state when the data portion thereof has been completely read, and to be in an unused state when otherwise.

12. The optical disc player system as claimed in claim 11, wherein said header scanning controller enables said reading pointer recorder to adjust the reading pointer to point to the next one of the sectors stored in said buffer memory that is in the unused state when the bitstream type indicated by the header portion of said one of the sectors being read from said buffer memory does not correspond to that of the bitstream request.