U.S. patent application number 14/431558 was filed with the patent office on 2015-09-03 for coding and decoding method and device with parameter set and electronic device.
The applicant listed for this patent is ZTE Corporation. Invention is credited to Ming Li, Ping Wu.
Application Number | 20150249837 14/431558 |
Document ID | / |
Family ID | 50322267 |
Filed Date | 2015-09-03 |
United States Patent
Application |
20150249837 |
Kind Code |
A1 |
Li; Ming ; et al. |
September 3, 2015 |
CODING AND DECODING METHOD AND DEVICE WITH PARAMETER SET AND
ELECTRONIC DEVICE
Abstract
Provided are methods and devices for encoding and decoding using
parameter sets, and electronic equipment. In the method for
encoding, an encoder determines parameter sets and/or virtual
parameter sets for a slice, wherein the virtual parameter set is a
data structure which is generated by loading information acquired
from a bitstream into a syntax structure of an existing parameter
set and/or a preset syntax structure and includes tool parameters
and/or control parameters; and the encoder writes identification
number (ID)(s) of the parameter sets and/or virtual parameter sets
into a bitstream. Using the method, encoding and decoding
efficiency is improved.
Inventors: |
Li; Ming; (Shenzhen, CN)
; Wu; Ping; (Shenzhen, CN) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
ZTE Corporation |
Shenzhen |
|
CN |
|
|
Family ID: |
50322267 |
Appl. No.: |
14/431558 |
Filed: |
September 2, 2013 |
PCT Filed: |
September 2, 2013 |
PCT NO: |
PCT/CN2013/082814 |
371 Date: |
April 28, 2015 |
Current U.S.
Class: |
375/240.26 |
Current CPC
Class: |
H04N 19/174 20141101;
H04N 19/46 20141101; H04N 19/597 20141101; H04N 19/70 20141101 |
International
Class: |
H04N 19/46 20060101
H04N019/46; H04N 19/70 20060101 H04N019/70; H04N 19/174 20060101
H04N019/174 |
Foreign Application Data
Date |
Code |
Application Number |
Sep 26, 2012 |
CN |
201210363925.3 |
Claims
1. A method for encoding using parameter sets, comprising:
determining, by an encoder, parameter sets and/or virtual parameter
sets for a slice, wherein the virtual parameter set is a data
structure which is generated by loading information acquired from a
bitstream into a syntax structure of an existing parameter set
and/or a preset syntax structure and comprises tool parameters
and/or control parameters; and writing, by the encoder,
identification numbers (IDs) of the parameter sets and/or virtual
parameter sets into a bitstream.
2. The method according to claim 1, wherein determining, by the
encoder, the parameter sets and/or virtual parameter sets for the
slice comprises: judging, by the encoder, whether at least one of
following conditions meets or not: tool parameters and/or control
parameters for encoding current slice are the same as tool
parameters and/or control parameters of the existing parameter set,
the tool parameters and/or control parameters for encoding the
current slice are the same as tool parameters and/or control
parameters in an existing virtual parameter set; if a judgment
result is positive, determining, by the encoder, the existing
parameter set with the same tool parameters and/or control
parameters as the parameter set for the slice, and/or determining
the existing virtual parameter set with the same tool parameters
and/or control parameters as the virtual parameter set for the
slice; and if the judgment result is negative, employing, by the
encoder, a generated parameter set as the parameter set for the
slice, and/or employing a constructed virtual parameter set as the
virtual parameter set for the slice; writing, by the encoder, the
IDs of the parameter sets and/or virtual parameter sets into the
bitstream comprises: writing, by the encoder, an ID of the
parameter set with the same tool parameters and/or control
parameters and/or an ID of the virtual parameter set with the same
tool parameters and/or control parameters into one of following
bitstreams: a Slice Header (SH) bitstream, a bitstream employing
the parameter set with the same tool parameters and/or control
parameters and/or a bitstream employing the virtual parameter set
with the same tool parameters and/or control parameters.
3. (canceled)
4. The method according to claim 1, wherein writing, by the
encoder, the IDs of the parameter sets and/or virtual parameter
sets into the bitstream comprises: when the encoder identifies that
the tool parameters and/or control parameters for the current
encoding slice are partially but not completely the same as the
tool parameters and/or control parameters of the parameter set,
setting, by the encoder, a value of a syntax element corresponding
to the ID of the parameter set in an SH of the current encoding
slice as a first preset value, and writing the first preset value
into the bitstream using an entropy coding method; and/or setting,
by the encoder, a value of a syntax element corresponding to a
parameter set ID of the parameter set comprising the tool
parameters and/or the control parameters as a second preset value,
and writing the second preset value into the bitstream using the
entropy coding method; when the encoder identifies that the tool
parameters and/or control parameters for the current encoding slice
are completely different from the tool parameters and/or control
parameters of the parameter set, generating, by the encoder, a
parameter set comprising the tool parameters and/or control
parameters for the current encoding slice; allocating an ID to the
parameter set for the current encoding slice; and setting the value
of the syntax element corresponding to the ID of the parameter set
in the SH of the current encoding slice to be the ID of the
generated parameter set, and writing the ID of the generated
parameter set into the bitstream using the entropy coding
method.
5. The method according to claim 1, wherein determining, by the
encoder, the parameter sets and/or virtual parameter sets for the
slice comprises: judging, by the encoder, whether the tool
parameters and/or control parameters for the current encoding slice
are partially but not completely the same as the tool parameters
and/or control parameters in the parameter sets or not, and a
virtual parameter set with tool parameters and/or control
parameters completely the same as the tool parameters and/or
control parameters for the current encoding slice is able to be
constructed or not; if a judgment result is positive, constructing,
by the encoder, a virtual parameter set by loading data in the
existing parameter sets as the virtual parameter set for the slice,
and determining the ID of the virtual parameter set for the slice;
and if the judgment result is negative, generating, by the encoder,
a parameter set comprising the tool parameters and/or the control
parameters, and allocating an ID to the generated parameter set;
writing, by the encoder, the IDs of the parameter sets and/or
virtual parameter sets into the bitstream comprises: setting, by
the encoder, the value of the syntax element corresponding to the
parameter set ID in the SH of the current encoding slice as the ID
of the generated virtual parameter set, and writing the value into
the bitstream using an entropy coding method; and/or setting, by
the encoder, the value of the syntax element corresponding to the
parameter set ID in the parameter set comprising the tool
parameters and/or the control parameters as the ID of the virtual
parameter set, and writing the ID of the generated virtual
parameter set into the bitstream using the entropy coding method;
or setting, by the encoder, the value of the syntax element
corresponding to the parameter set ID in the SH of the current
encoding slice as the ID of the generated parameter set, and
writing the ID of the generated parameter set into the bitstream
using the entropy coding method.
6. (canceled)
7. (canceled)
8. A method for decoding using parameter sets, comprising:
generating, by a decoder, a virtual parameter set, wherein the
virtual parameter set is a data structure which is generated by
loading information acquired from a bitstream into a structure of
an existing parameter set and/or a preset data element structure
and comprises tool parameters and/or control parameters;
allocating, by the decoder, an identification number (ID) to the
virtual parameter set; and activating, by the decoder, the virtual
parameter set according to the ID of the virtual parameter set, and
configuring tool parameters and/or control parameters for slice
decoding process according to parameters in the virtual parameter
set.
9. (canceled)
10. (canceled)
11. The method according to claim 8, wherein generating, by the
decoder, the virtual parameter set comprises: generating, by the
decoder, the virtual parameter set by loading information acquired
from one or more independent elements of the bitstream into a
syntax structure of the existing parameter set or a preset syntax
structure, wherein the virtual parameter set comprises all and/or a
part of information comprised in the one or more independent
elements in the bitstream; allocating, by the decoder, the ID to
the virtual parameter set comprises: allocating, by the decoder, an
ID reserved for the virtual parameter set to the virtual parameter
set.
12. The method according to claim 11, wherein generating, by the
decoder, the virtual parameter set by loading the information
acquired from one or more independent elements of the bitstream
into the syntax structure of the existing parameter set or the
preset syntax structure comprises: decomposing, by the decoder, the
ID of the parameter set directly or indirectly referred to by the
slice into index numbers of the one or more independent elements
for constructing the virtual parameter set according to the ID of
the parameter set directly or indirectly referred to by the slice;
and acquiring, by the decoder, the information from the one or more
independent elements in the bitstream according to the index
numbers of the one or more independent elements, and generating the
virtual parameter set according to the syntax structure of the
existing parameter set or the preset syntax structure.
13.-22. (canceled)
23. A device for encoding using parameter sets, wherein the device
for encoding using parameter sets is applied to an encoder and
comprises: a first determination component, configured to determine
parameter sets and/or virtual parameter sets for a slice, wherein
the virtual parameter set is a data structure which is generated by
loading information acquired from a bitstream into a data element
structure of an existing parameter set and/or a preset data element
structure and comprises tool parameters and/or control parameters;
and a first processing component, configured to write
identification numbers (IDs) of the parameter sets and/or virtual
parameter sets into a bitstream.
24. The device according to claim 23, wherein the first
determination component comprises: a first judgment component,
configured to judge whether at least one of following conditions
meets or not: tool parameters and/or control parameters for
encoding a current slice are the same as tool parameters and/or
control parameters of the existing parameter set, the tool
parameters and/or control parameters for encoding the current slice
are the same as tool parameters and/or control parameters in an
existing virtual parameter set; a second determination component,
configured to, if a judgment result of the first judgment component
is positive, determine the existing parameter set which is
determined by the first judgment component to have the same tool
parameters and/or control parameters as the parameter set for the
slice, and/or determine the existing virtual parameter set which is
determined by the first judgment component to have the same tool
parameters and/or control parameters as the virtual parameter set
for the slice; and a third determination component, configured to,
if the judgment result of the first judgment component is negative,
employ a generated parameter set as the parameter set for the
slice, and/or employ a constructed virtual parameter set as the
virtual parameter set for the slice; the first processing component
is configured to write an ID of the parameter set which is
determined by the first judgment component to have the same tool
parameters and/or control parameters and/or an ID of the virtual
parameter set which is determined by the first judgment component
to have the same tool parameters and/or control parameters into one
of following bitstreams: a Slice Header (SH) bitstream, a bitstream
employing the parameter set with the same tool parameters and/or
control parameters and/or a bitstream employing the virtual
parameter set with the same tool parameters and/or control
parameters.
25. (canceled)
26. The device according to claim 23, wherein the first processing
component comprises: a second judgment component, configured to
identify that the tool parameters and/or control parameters for the
current encoding slice are partially but not completely the same as
the tool parameters and/or control parameters of the parameter set;
a first setting component, configured to set a value of a syntax
element corresponding to the ID of the parameter set in an SH of
the current encoding slice as a first preset value; a second
processing component, configured to write the first preset value
into the bitstream using an entropy coding method; and/or a second
setting component, configured to set a value of a syntax element
corresponding to a parameter set ID of the parameter set comprising
the tool parameters and/or the control parameters as a second
preset value; a third processing component, configured to write the
second preset value into the bitstream using the entropy coding
method; a third judgment component, configured to identify that the
tool parameters and/or control parameters for the current encoding
slice are completely different from the tool parameters and/or
control parameters of the parameter set; a first generation
component, configured to generate a parameter set comprising the
tool parameters and/or control parameters for the current encoding
slice; a first allocation component, configured to allocate an ID
to the parameter set for the current encoding slice; a third
setting component, configured to set the value of the syntax
element corresponding to the ID of the parameter set in the SH of
the current encoding slice to be the ID of the generated parameter
set; and a fourth processing component, configured to write the ID
of the generated parameter set into the bitstream using the entropy
coding method.
27. The device according to claim 23, wherein the first
determination component comprises: a fourth judgment component,
configured to judge, by the encoder, whether the tool parameters
and/or control parameters for the current encoding slice are
partially but not completely the same as the tool parameters and/or
control parameters in the parameter set or not, and a virtual
parameter set with a tool parameters and/or control parameters
completely the same as the tool parameters and/or control
parameters for the current encoding slice is able to be constructed
or not; a fifth processing component, configured to, if a judgment
result of the fourth judgment component is positive, construct, by
the encoder, a virtual parameter set based on the data in the
existing parameter sets as the virtual parameter set for the slice;
a fourth determination component, configured to determine the ID of
the virtual parameter set for the slice; a second generation
component, configured to, if the judgment result of the fourth
judgment component is negative, generate a parameter set comprising
the tool parameters and/or the control parameters; and a second
allocation component, configured to allocate an ID to the generated
parameter set; the first processing component comprises: a fourth
setting component, configured to set the value of the syntax
element corresponding to the parameter set ID in the SH of the
current encoding slice as the ID of the generated virtual parameter
set; a fifth processing component, configured to write the value
into the bitstream using an entropy coding method; and/or a fifth
setting component, configured to set the value of the syntax
element corresponding to the parameter set ID in the parameter set
comprising the tool parameters and/or the control parameters as the
ID of the virtual parameter set; a sixth processing component,
configured to write the ID of the generated virtual parameter set
into the bitstream using the entropy coding method; or a sixth
setting component, configured to set the value of the syntax
element corresponding to the parameter set ID in the SH of the
current encoding slice as the ID of the generated parameter set;
and a seventh processing component, configured to write the ID of
the generated parameter set into the bitstream using the entropy
coding method.
28. (canceled)
29. A device for decoding using parameter sets, wherein the device
for decoding using parameter sets is applied to a decoder and
comprises: a third generation component, configured to generate a
virtual parameter set, wherein the virtual parameter set is a data
structure which is generated by loading information acquired from a
bitstream into a data element structure of an existing parameter
set and/or a preset data element structure and comprises tool
parameters and/or control parameters; a third allocation component,
configured to allocate an identification number (ID) to the virtual
parameter set; a first activation component, configured to activate
the virtual parameter set according to the ID of the virtual
parameter set; and a first decoding component, configured to
configure tool parameters and/or control parameters for slice
decoding process according to parameters in the virtual parameter
set.
30. (canceled)
31. (canceled)
32. The device according to claim 29, wherein the third generation
component is configured to generate the virtual parameter set by
loading information acquired from one or more independent elements
of the bitstream into a syntax structure of the existing parameter
set or a preset syntax structure, wherein the virtual parameter set
comprises all and/or a part of information comprised in the one or
more independent elements in the bitstream; the third allocation
component comprises: a fourth allocation component, configured to
allocate an ID reserved for the virtual parameter set to the
virtual parameter set.
33. The device according to claim 32, wherein the third generation
component comprises: a decomposition component, configured to
decompose the ID of the parameter set directly or indirectly
referred to by the slice into index numbers of the one or more
independent elements for constructing the virtual parameter set
according to the ID of the parameter set directly or indirectly
referred to by the slice; and a fourth generation component,
configured to acquire the information from the one or more
independent elements in the bitstream according to the index
numbers of the one or more independent elements, and generate the
virtual parameter set according to the syntax structure of the
existing parameter set or the preset syntax structure.
34.-41. (canceled)
Description
TECHNICAL FIELD
[0001] The disclosure relates to the field of communication, in
particular to methods and devices for encoding and decoding using
parameter sets, and electronic equipment.
BACKGROUND
[0002] In H.264/Advanced Video Coding (AVC) compatible
Three-Dimensional Video (3DV) coding standard 3D-AVC (AVC
compatible video with depth information) which is an active
standardization project at present, Depth-Range-based Weighted
Prediction (DRWP) and View Synthesis Prediction (VSP) encoding and
decoding processes require the use of Depth Parameters (DPs),
including maximum depth (marked as "ZFar"), minimum depth (marked
as "ZNear"), camera parameters (such as a focal distance) and the
like, which are used in a depth map generation process. At present,
3D-AVC encodes and transmits DPs in a subset Sequence Parameter Set
(subset SPS or sub-SPS, which is a type of parameter set) and a
Depth Parameter Set (DPS) respectively.
[0003] 3D-AVC determines whether the DPs in the sub-SPS or the DPS
are to be used by judging whether the value of syntax element
dps_id in Slice Header (SH) is equal to "0" or not. The decoding
process is described as follows.
[0004] In the decoding process, a decoder parses control parameters
in the SH. If the DRWP and/or VSP is used by the decoding process,
the decoder further parses a field corresponding to the syntax
element dps_id in the SH. If the value of the dps_id is equal to 0,
the decoder uses the DPs in the sub-SPS; while if the value of the
dps_id is more than 0, the decoder activates the DPS with its
identification number (ID) value equal to dps_id following
parameter set activation process, and the DPs in this activated DPS
are used in the decoding process.
[0005] Corresponding to the decoding process, the encoding process
is as follows.
[0006] In the encoding process, when DPs are used, an encoder
writes an ID of the DPS into the field corresponding to the dps_id
in the SH. If the DPs in the sub-SPS are used, value "0" is written
into the field corresponding to the syntax element dps_id of the
SH; while if the DPs in a certain DPS are used, an ID value of this
DPS is written into the field corresponding to the syntax element
dps_id of the SH, and this ID value is equal to the value of the
syntax element depth_parameter_set_id in this DPS.
[0007] In order to improve the encoding efficiency, predictive
encoding may further be used for the DPs in the DPS, and a
prediction mode and prediction reference information may be encoded
in the DPS. The prediction reference may be the DPs in another DPS,
and may also be the DPs in a sub-SPS. Therefore, 3D-AVC stores the
DPs decoded from DPS in an array and employs dps_id as the index
parameter for accessing the array, and permanently employs an array
element corresponding to an index parameter "0" as a storage
location for the DPs in the sub-SPS. In this way, 3D-AVC identifies
the prediction reference of the DPs in the DPS directly by the
index parameter of the DPs in the array.
[0008] Another possible implementation mode different from the SH
of 3D-AVC is as follows: an independent flag is added to identify
whether the DPs used for a slice decoding process are from the
sub-SPS or not, instead of judging whether the DPs in the sub-SPS
or the DPS are to be used by judging whether the dps_id is 0 or
not. When the DPs in the sub-SPS are not used, the DPS with its ID
value equal to dps_id is activated, and current slice is decoded
using the DPs in the activated DPS. The method is not included in
3D-AVC because an additional flag and its corresponding decoding
operations are required to be added.
[0009] Main defects of the conventional method used by 3D-AVC are
inconsistency with general operations of a parameter set, which
introduces additional judgment and special condition processing
flows in an implementation flow. Main limitations of the
conventional method are as follows.
[0010] First, the operations related to SPS/sub-SPS in the decoding
process are inconsistent with general processing flows of the
parameter set. "Setting data included in the parameter set to be
data actually used in the decoding process immediately after the
parameter set is activated" is one of general flows of the
parameter set. In slice decoding process, the decoder activates the
sub-SPS at first. For a slice using the DPs, the decoder can
determine to update information in a storage element corresponding
to the index parameter "0" in the array storing DP data, but cannot
determine whether to use DP information of the activated sub-SPS or
not in a subsequent decoding process of the slice after activating
the sub-SPS, since it has to wait for DRWP and/or VSP flags and
dps_id information.
[0011] Second, as mentioned above, the decoder cannot determine the
validity range of the DPs included in the sub-SPS in the decoding
process, namely whether the DPs included in the sub-SPS are
applicable to the entire decoding process or only used for updating
the array storing the DP data, immediately after the sub-SPS is
activated.
[0012] Third, the DPS operations in the decoding process are
inconsistent with the general processing flows of the parameter
set. "That the decoder activates the parameter set with its ID
equal to the value of the corresponding syntax element in the SH
and simultaneously sets a previously activated parameter set with a
different ID value into an inactive state" is also one of the
general flows of the parameter set. In the slice decoding process,
the condition that the value of dps_id is "0" is required to be
specially processed, that is, the information in the storage
element corresponding to the index parameter "0" in the array
storing the DP data is assigned to a variable corresponding to the
DP in a current slice decoding process, and a special condition
processing flow of the decoder is added.
[0013] For the problem of relatively complex flows of methods for
encoding/decoding using parameter sets in a related art, there is
yet no effective solution.
SUMMARY OF THE DISCLOSURE
[0014] For the problem of relatively complex flows of methods for
encoding/decoding using parameter sets in the related art, the
embodiments of the disclosure provide methods and devices for
encoding and decoding using parameter sets, and electronic
equipment, so as to at least solve the problem.
[0015] According to one embodiment of the disclosure, a method for
encoding using parameter sets is provided, which includes: an
encoder determines parameter sets and/or virtual parameter sets for
a slice, wherein the virtual parameter set is a data structure
which is generated by loading information acquired from a bitstream
into a syntax structure of an existing parameter set and/or a
preset syntax structure and includes tool parameters and/or control
parameters; and the encoder writes IDs of the parameter sets and/or
virtual parameter sets into a bitstream.
[0016] In an example embodiment, the step that the encoder
determines the parameter sets and/or virtual parameter sets for the
slice includes: the encoder judges whether at least one of
following conditions meets or not: tool parameters and/or control
parameters for encoding current slice are the same as tool
parameters and/or control parameters of the existing parameter set,
the tool parameters and/or control parameters for encoding the
current slice are the same as tool parameters and/or control
parameters in an existing virtual parameter set; if a judgment
result is positive, the encoder determines the existing parameter
set with the same tool parameters and/or control parameters as the
parameter set for the slice, and/or determines the existing virtual
parameter set with the same tool parameters and/or control
parameters as the virtual parameter set for the slice; and if the
judgment result is negative, the encoder employs a generated
parameter set as the parameter set for the slice, and/or employs a
constructed virtual parameter set as the virtual parameter set for
the slice.
[0017] In an example embodiment, the step that the encoder writes
the IDs of the parameter sets and/or virtual parameter sets into
the bitstream includes: the encoder writes an ID of the parameter
set with the same tool parameters and/or control parameters and/or
an ID of the virtual parameter set with the same tool parameters
and/or control parameters into one of the following bitstreams: an
SH bitstream, a bitstream employing the parameter set with the same
tool parameters and/or control parameters and/or a bitstream
employing the virtual parameter set with the same tool parameters
and/or control parameters.
[0018] In an example embodiment, the step that the encoder writes
the IDs of the parameter sets and/or virtual parameter sets into
the bitstream includes: when the encoder identifies that the tool
parameters and/or control parameters for the current encoding slice
are partially but not completely the same as the tool parameters
and/or control parameters of the parameter set, the encoder sets a
value of a syntax element corresponding to the ID of the parameter
set in an SH of the current encoding slice as a first preset value,
and writes the first preset value into the bitstream using an
entropy coding method; and/or the encoder sets a value of a syntax
element corresponding to a parameter set ID in the parameter set
including the tool parameters and/or the control parameters as a
second preset value, and writes the second preset value into the
bitstream using the entropy coding method; when the encoder
identifies that the tool parameters and/or control parameters for
the current encoding slice are completely different from the tool
parameters and/or control parameters of the parameter set, the
encoder generates a parameter set including the tool parameters
and/or control parameters for the current encoding slice; an ID is
allocated to the parameter set for the current encoding slice; and
the value of the syntax element corresponding to the ID of the
parameter set in the SH of the current encoding slice is set to be
the ID of the generated parameter set, and the ID of the generated
parameter set is written into the bitstream using the entropy
coding method.
[0019] In an example embodiment, the step that the encoder
determines the parameter sets and/or virtual parameter sets for the
slice includes: the encoder judges whether the tool parameters
and/or control parameters for the current encoding slice are
partially but not completely the same as the tool parameters and/or
control parameters in the parameter sets or not, and a virtual
parameter set with tool parameters and/or control parameters
completely the same as the tool parameters and/or control
parameters for the current encoding slice is able to be constructed
or not; if a judgment result is positive, the encoder constructs a
virtual parameter set by loading data in the existing parameter
sets as the virtual parameter set for the slice, and determines the
ID of the virtual parameter set for the slice; and if the judgment
result is negative, the encoder generates a parameter set including
the tool parameters and/or the control parameters, and allocates an
ID to the generated parameter set.
[0020] In an example embodiment, the step that the encoder writes
the IDs of the parameter sets and/or virtual parameter sets into
the bitstream includes: the encoder sets the value of the syntax
element corresponding to the parameter set ID in the SH of the
current encoding slice as the ID of the generated virtual parameter
set, and writes the value into the bitstream using an entropy
coding method; and/or the encoder sets the value of the syntax
element corresponding to the parameter set ID in the parameter set
including the tool parameters and/or the control parameters as the
ID of the virtual parameter set, and writes the ID of the generated
virtual parameter set into the bitstream using the entropy coding
method; or the encoder sets the value of the syntax element
corresponding to the parameter set ID in the SH of the current
encoding slice as the ID of the generated parameter set, and writes
the ID of the generated parameter set into the bitstream using the
entropy coding method.
[0021] In an example embodiment, the tool parameters and/or the
control parameters are depth information parameters, and the tool
parameters and/or the control parameters include at least one of:
parameters for a digital presentation of depth information,
attribute parameters for camera imaging system and camera
arrangement manner related parameters.
[0022] According to another embodiment of the disclosure, a method
for decoding using parameter sets is provided, which includes: a
decoder generates virtual parameter sets, wherein the virtual
parameter set is a data structure which is generated by loading
information acquired from a bitstream into a data element structure
of an existing parameter set and/or a preset data element structure
and includes tool parameters and/or control parameters; the decoder
allocates an identification number (ID) to the virtual parameter
set; and the decoder activates the virtual parameter set according
to the ID of the virtual parameter set, and configures tool
parameters and/or control parameters for slice decoding process
according to parameters in the virtual parameter set.
[0023] In an example embodiment, before the decoder generates the
virtual parameter set, the method further includes: the decoder
determines that one or more types of preset tool parameters and/or
control parameters are able to be acquired from one or more
independent elements in the bitstream.
[0024] In an example embodiment, before the decoder generates the
virtual parameter set, the method further includes: the decoder
acquires IDs of parameter sets directly and/or indirectly referred
to by a slice from the bitstream; and the decoder determines that
the ID values of the parameter sets directly and/or indirectly
referred to by the slice are out of a preset value range.
[0025] In an example embodiment, the step that the decoder
generates the virtual parameter set includes: the decoder generates
the virtual parameter set by loading information acquired from one
or more independent elements of the bitstream into a syntax
structure of the existing parameter set or a preset syntax
structure, wherein the virtual parameter set includes all and/or a
part of information included in the one or more independent
elements in the bitstream.
[0026] In an example embodiment, the step that the decoder
generates the virtual parameter set by loading the information
acquired from one or more independent elements of the bitstream
into the syntax structure of the existing parameter set or the
preset syntax structure includes: the decoder decomposes the ID of
the parameter set directly or indirectly referred to by the slice
into index numbers of the one or more independent elements for
constructing the virtual parameter set according to the ID of the
parameter set directly or indirectly referred to by the slice; and
the decoder acquires the information from the one or more
independent elements in the bitstream according to the index
numbers of the one or more independent elements, and generates the
virtual parameter set according to the syntax structure of the
existing parameter set or the preset syntax structure.
[0027] In an example embodiment, the step that the decoder acquires
the information from the one or more independent elements in the
bitstream according to the obtained index numbers of the
independent elements, and generates the virtual parameter set
according to the syntax structure of the existing parameter set or
the preset syntax structure includes: the decoder constructs the
virtual parameter set by using all or a part of tool parameters
and/or control parameters included in one or more front independent
elements according to the parsing order of the index numbers of
multiple independent elements.
[0028] In an example embodiment, the index numbers of the
independent elements are IDs of existing parameter sets.
[0029] In an example embodiment, the independent elements in the
bitstream are data elements divided by delimiters periodically
appearing in the bitstream.
[0030] In an example embodiment, the data elements are Network
Abstraction Layer (NAL) units.
[0031] In an example embodiment, the step that the decoder
allocates the ID to the virtual parameter set includes: the decoder
allocates an ID reserved for the virtual parameter set to the
virtual parameter set.
[0032] In an example embodiment, the step that the decoder
allocates the ID reserved for the virtual parameter set to the
virtual parameter set includes: the decoder allocates a reserved
fixed numerical value to the virtual parameter set as the ID of the
virtual parameter set.
[0033] In an example embodiment, the step that the decoder
allocates the ID to the virtual parameter set includes: the decoder
allocates a numerical value out of a preset range to the virtual
parameter set as the ID of the virtual parameter set.
[0034] In an example embodiment, the step that the decoder
allocates the numerical value out of the preset range to the
virtual parameter set as the ID of the virtual parameter set
includes: the decoder employs a numerical value of a parameter set
ID out of the preset range in the bitstream of the slice as the ID
of the virtual parameter set.
[0035] In an example embodiment, the method further includes: the
decoder activates an existing virtual parameter set.
[0036] In an example embodiment, the step that the decoder
activates the existing virtual parameter set includes: the decoder
activates a virtual parameter set which is configured for current
slice and has been generated before decoding the current slice with
the same virtual parameter set ID; and the decoder configures the
tool parameters and/or control parameters for the slice decoding
process using parameters in the activated virtual parameter
set.
[0037] According to still another embodiment of the disclosure, a
device for encoding using parameter sets is also provided, which is
applied to an encoder and includes: a first determination
component, configured to determine parameter sets and/or virtual
parameter sets for a slice, wherein the virtual parameter set is a
data structure which is generated by loading information acquired
from a bitstream into a syntax structure of an existing parameter
set and/or a preset syntax structure and includes tool parameters
and/or control parameters; and a first processing component,
configured to write IDs of the parameter sets and/or virtual
parameter sets into the bitstream.
[0038] In an example embodiment, the first determination component
includes: a first judgment component, configured to judge whether
at least one of the following conditions meets or not: tool
parameters and/or control parameters for encoding current slice are
the same as tool parameters and/or control parameters of the
existing parameter set, the tool parameters and/or control
parameters for encoding the current slice are the same as tool
parameters and/or control parameters in an existing virtual
parameter set; a second determination component, configured to, if
a judgment result of the first judgment component is positive,
determine the existing parameter set which is determined by the
first judgment component to have the same tool parameters and/or
control parameters as the parameter set for the slice, and/or
determine the existing virtual parameter set which is determined by
the first judgment component to have the same tool parameters
and/or control parameters as the virtual parameter set for the
slice; and a third determination component, configured to, if the
judgment result of the first judgment component is negative, employ
a generated parameter set as the parameter set for the slice,
and/or employ a constructed virtual parameter set as the virtual
parameter set for the slice.
[0039] In an example embodiment, the first processing component is
configured to write an ID of the parameter set which is determined
by the first judgment component to have the same tool parameters
and/or control parameters and/or an ID of the virtual parameter set
which is determined by the first judgment component to have the
same tool parameters and/or control parameters into one of the
following bitstreams: an SH bitstream, a bitstream employing the
parameter set with the same tool parameters and/or control
parameters and/or a bitstream employing the virtual parameter set
with the same tool parameters and/or control parameters.
[0040] In an example embodiment, the first processing component
includes: a second judgment component, configured to identify that
the tool parameters and/or control parameters for the current
encoding slice are partially but not completely the same as the
tool parameters and/or control parameters of the parameter set; a
first setting component, configured to set a value of a syntax
element corresponding to the ID of the parameter set in SH of the
current encoding slice as a first preset value; a second processing
component, configured to write the first preset value into the
bitstream using an entropy coding method; and/or a second setting
component, configured to set a value of a syntax element
corresponding to a parameter set ID of the parameter set including
the tool parameters and/or the control parameters as a second
preset value; a third processing component, configured to write the
second preset value into the bitstream using the entropy coding
method; a third judgment component, configured to identify that the
tool parameters and/or control parameters for the current encoding
slice are completely different from the tool parameters and/or
control parameters of the parameter set; a first generation
component, configured to generate a parameter set including the
tool parameters and/or control parameters for the current encoding
slice; a first allocation component, configured to allocate an ID
to the parameter set for the current encoding slice; a third
setting component, configured to set the value of the syntax
element corresponding to the ID of the parameter set in the SH of
the current encoding slice to be the ID of the generated parameter
set; and a fourth processing component, configured to write the ID
of the generated parameter set into the bitstream using the entropy
coding method.
[0041] In an example embodiment, the first determination component
includes: a fourth judgment component, configured to judge, by the
encoder, whether the tool parameters and/or control parameters for
the current encoding slice are partially but not completely the
same as the tool parameters and/or control parameters in the
parameter set or not, and a virtual parameter set with a tool
parameters and/or control parameters completely the same as the
tool parameters and/or control parameters for the current encoding
slice is able to be constructed or not; a fifth processing
component, configured to, if a judgment result of the fourth
judgment component is positive, construct, by the encoder, a
virtual parameter set based on data in the existing parameter sets
as the virtual parameter set for the slice; a fourth determination
component, configured to determine the ID of the virtual parameter
set for the slice; a second generation component, configured to, if
the judgment result of the fourth judgment component is negative,
generate a parameter set including the tool parameters and/or the
control parameters; and a second allocation component, configured
to allocate an ID to the generated parameter set.
[0042] In an example embodiment, the first processing component
includes: a fourth setting component, configured to set the value
of the syntax element corresponding to the parameter set ID in the
SH of the current encoding slice as the ID of the generated virtual
parameter set; a fifth processing component, configured to write
the value into the bitstream using an entropy coding method; and/or
a fifth setting component, configured to set the value of the
syntax element corresponding to the parameter set ID in the
parameter set including the tool parameters and/or the control
parameters as the ID of the virtual parameter set; a sixth
processing component, configured to write the ID of the generated
virtual parameter set into the bitstream using the entropy coding
method; or a sixth setting component, configured to set the value
of the syntax element corresponding to the parameter set ID in the
SH of the current encoding slice as the ID of the generated
parameter set; and a seventh processing component, configured to
write the ID of the generated parameter set into the bitstream
using the entropy coding method.
[0043] According to still another embodiment of the disclosure, a
device for decoding using parameter sets is also provided, which is
applied to a decoder and includes: a third generation component,
configured to generate a virtual parameter set, wherein the virtual
parameter set is a data structure which is generated by loading
information acquired from a bitstream into a data element structure
of an existing parameter set and/or a preset data element structure
and includes tool parameters and/or control parameters; a third
allocation component, configured to allocate an ID to the virtual
parameter set; a first activation component, configured to activate
the virtual parameter set according to the ID of the virtual
parameter set; and a first decoding component, configured to
configure tool parameters and/or control parameters for a slice
decoding process according to parameters in the virtual parameter
set.
[0044] In an example embodiment, the device further includes: a
fifth judgment component, configured to determine that one or more
types of preset tool parameters and/or control parameters are able
to be acquired from one or more independent elements in the
bitstream.
[0045] In an example embodiment, the device further includes: an
acquisition component, configured to acquire IDs of parameter sets
directly and/or indirectly referred to by a slice from the
bitstream; and a sixth judgment component, configured to determine
that values of the IDs of the parameter sets directly and/or
indirectly referred to by the slice are out of a preset value
range.
[0046] In an example embodiment, the third generation component is
configured to generate the virtual parameter set by loading
information acquired from one or more independent elements of the
bitstream into a syntax structure of the existing parameter set or
a preset syntax structure, wherein the virtual parameter set
includes all and/or a part of information included in the one or
more independent elements in the bitstream.
[0047] In an example embodiment, the third generation component
includes: a decomposition component, configured to decompose the ID
of the parameter set directly or indirectly referred to by the
slice into index numbers of the one or more independent elements
for constructing the virtual parameter set according to the ID of
the parameter set directly or indirectly referred to by the slice;
and a fourth generation component, configured to acquire the
information from the one or more independent elements in the
bitstream according to the index numbers of the one or more
independent elements, and generate the virtual parameter set
according to the syntax structure of the existing parameter set or
the preset syntax structure.
[0048] In an example embodiment, the fourth generation component is
configured to construct the virtual parameter set based on all or a
part of tool parameters and/or control parameters included in one
or more front independent elements according to the parsing order
of the index numbers of multiple independent elements.
[0049] In an example embodiment, the third allocation component
includes: a fourth allocation component, configured to allocate an
ID reserved for the virtual parameter set to the virtual parameter
set.
[0050] In an example embodiment, the fourth allocation component
allocates a reserved fixed numerical value to the virtual parameter
set as the ID of the virtual parameter set.
[0051] In an example embodiment, the third allocation component
includes: a fifth allocation component, configured to allocate a
numerical value out of a preset range to the virtual parameter set
as the ID of the virtual parameter set.
[0052] In an example embodiment, the fifth allocation component is
configured to employ, by the decoder, a numerical value of a
parameter set ID out of the preset range in the bitstream of the
slice as the ID of the virtual parameter set.
[0053] In an example embodiment, the device further includes: a
second activation component, configured to activate an existing
virtual parameter set.
[0054] In an example embodiment, the second activation component
includes: a third activation component, configured to activate a
virtual parameter set which is configured for current slice and has
been generated before decoding the current slice with the same
virtual parameter set ID; and a second decoding component,
configured to configure the tool parameters and/or control
parameters for the slice decoding process using parameters in the
activated virtual parameter set.
[0055] According to still another embodiment of the disclosure,
electronic equipment is also provided, which includes: the
above-mentioned device for encoding using parameter sets and/or the
above-mentioned device for decoding using parameter sets.
[0056] According to the embodiments of the disclosure, the virtual
parameter set is used to encode and decode data, so that the
problem of relatively complex flows of methods for encoding and
decoding using parameters in the related art is solved, and the
effect of improving encoding and decoding efficiency is further
achieved.
BRIEF DESCRIPTION OF THE DRAWINGS
[0057] The drawings are described here to provide further
understanding of the disclosure, and form a part of the disclosure.
The schematic embodiments and description of the disclosure are
used to explain the disclosure, and do not form improper limits to
the disclosure. In the drawings:
[0058] FIG. 1 is a flowchart of a method for encoding parameters
according to an embodiment of the disclosure;
[0059] FIG. 2 is a flowchart of a method for decoding parameters
according to an embodiment of the disclosure;
[0060] FIG. 3 is a structure diagram of a device for encoding
parameters according to an embodiment of the disclosure;
[0061] FIG. 4 is an example structure diagram of a device for
encoding parameters according to an embodiment of the
disclosure;
[0062] FIG. 5 is a structure diagram of a device for decoding
parameters according to an embodiment of the disclosure;
[0063] FIG. 6 is an example structure diagram of a device for
decoding parameters according to an embodiment of the
disclosure;
[0064] FIG. 7 is a structure diagram of electronic equipment
according to an embodiment of the disclosure;
[0065] FIG. 8 is a flowchart of a method for decoding according to
an embodiment of the disclosure;
[0066] FIG. 9 is a flowchart of a method for encoding according to
an embodiment of the disclosure;
[0067] FIG. 10 is a first flowchart of a method for decoding
according to an example embodiment of the disclosure;
[0068] FIG. 11 is a first flowchart of a method for encoding
according to an example embodiment of the disclosure;
[0069] FIG. 12 is a second flowchart of a method for decoding
according to an example embodiment of the disclosure; and
[0070] FIG. 13 is a second flowchart of a method for encoding
according to an example embodiment of the disclosure;
DETAILED DESCRIPTION OF THE EMBODIMENTS
[0071] The disclosure is described below with reference to the
drawings and embodiments in detail. It is important to note that
the embodiments of the disclosure and the characteristics in the
embodiments can be combined under the condition of no
conflicts.
[0072] An example embodiment provides a method for encoding using
parameter sets. FIG. 1 is a flowchart of a method for encoding
parameters according to an embodiment of the disclosure. As shown
in FIG. 1, the method includes the following Step S102 to Step
S104.
[0073] Step S102: an encoder determines parameter sets and/or
virtual parameter sets for a slice, wherein the virtual parameter
set is a data structure which is generated by loading information
acquired from a bitstream into a syntax structure of an existing
parameter set and/or a preset syntax structure and includes tool
parameters and/or control parameters.
[0074] Step S104: the encoder writes IDs of the parameter sets
and/or virtual parameter sets into the bitstream.
[0075] By the steps, the encoder writes the IDs of the parameter
sets and/or virtual parameter sets for the slice into the
bitstream, so that a flow of determining encoding parameters in an
encoding process by the encoder can be simplified, and encoding and
decoding efficiency is further improved.
[0076] During implementation, the parameter sets and/or virtual
parameter sets for the slice may be determined in multiple manners.
For example: tool parameters and/or control parameters for encoding
current slice may be judged whether to be the same as tool
parameters and/or control parameters of the existing parameter set
and/or an existing virtual parameter set or not for determination.
In an example embodiment, the encoder determines whether at least
one of the following conditions meets or not: the tool parameters
and/or control parameters for encoding the current slice are the
same as the tool parameters and/or control parameters of the
existing parameter set; and the tool parameters and/or control
parameters for encoding the current slice are the same as tool
parameters and/or control parameters in an existing virtual
parameter set. When the judgment result is positive, the encoder
may determine the existing parameter set with the same tool
parameters and/or control parameters as the parameter set for the
slice, and/or determine the existing virtual parameter set with the
same tool parameters and/or control parameters as the virtual
parameter set for the slice. When the judgment result is negative,
the encoder may generate a parameter set or construct a virtual
parameter set, employ the generated parameter set as the parameter
set for the slice and/or employ the constructed virtual parameter
set as the virtual parameter set for the slice. By this example
implementation mode, the use of the existing parameter set in the
encoding process is realized, so that encoding compatibility and
efficiency are improved.
[0077] Corresponding to the example implementation mode, the IDs of
the parameter sets and/or virtual parameter sets may be written
into the bitstream in a manner as follows in order to improve the
accuracy of writing of IDs into the bitstream. The encoder may
write an ID of the parameter set with the same tool parameters
and/or control parameters and/or an ID of the virtual parameter set
with the same tool parameters and/or control parameters into one of
the following bitstreams: an SH bitstream, a bitstream employing
the parameter set with the same tool parameters and/or control
parameters and/or a bitstream employing the virtual parameter set
with the same tool parameters and/or control parameters.
[0078] During implementation, the IDs may be written into the
bitstream in manners as follows according to a relationship between
the tool parameters and/or control parameters for the current
encoding slice and the tool parameters and/or control parameters of
the parameter set.
[0079] Manner 1: when the tool parameters and/or control parameters
for the current encoding slice are identified to be partially but
not completely the same as the tool parameters and/or control
parameters of the parameter set, the encoder sets a value of a
syntax element corresponding to the ID of the parameter set in an
SH of the current encoding slice (i.e., the slice currently being
processed by the encoder) as a first preset value, and writes the
first preset value into the bitstream using an entropy coding
method; and/or the encoder sets a value of a syntax element
corresponding to a parameter set ID of the parameter set including
the tool parameters and/or the control parameters as a second
preset value, and writes the second preset value into the bitstream
using the entropy coding method.
[0080] Manner 2: when the encoder identifies that the tool
parameters and/or control parameters for the current encoding slice
are completely different from the tool parameters and/or control
parameters of the parameter set, the encoder generates a parameter
set including the tool parameters and/or control parameters for the
current encoding slice; an ID is allocated to the parameter set for
the current encoding slice; and the value of the syntax element
corresponding to the ID of the parameter set in the SH of the
current encoding slice is set to be the ID of the generated
parameter set, and the ID of the generated parameter set is written
into the bitstream using the entropy coding method.
[0081] During implementation, the parameter sets and/or virtual
parameter sets for the slice may also be determined by the encoder
in a manner of judging whether the tool parameters and/or control
parameters for the current encoding slice are partially but not
completely the same as the tool parameters and/or control
parameters in the parameter set or not, and a virtual parameter set
with a tool parameters and/or control parameters completely the
same as the tool parameters and/or control parameters for the
current encoding slice is able to be constructed or not.
[0082] Manner 1: when the judgment result is positive, the encoder
may construct a virtual parameter set by loading data in the
existing parameter sets as the virtual parameter set for the slice,
and determine the ID of the virtual parameter set for the
slice.
[0083] Manner 2: when the judgment result is negative, the encoder
generates a parameter set including the tool parameters and/or the
control parameters, and allocates an ID to the generated parameter
set.
[0084] Corresponding to the example implementation mode, the
encoder may write the IDs of the parameter sets and/or virtual
parameter sets into the bitstream in one of manners as follows.
[0085] Manner 1: the encoder sets values of a syntax element
corresponding to the ID of the parameter set in the SHs included in
an Access Element (AU) where the current encoding slice is located
as an ID of the generated virtual parameter set, and writes the
value into the bitstream using an entropy coding method; and/or the
encoder sets the value of the syntax element corresponding to the
parameter set ID in the parameter set including the tool parameters
and/or the control parameters as the ID of the virtual parameter
set, and writes the ID of the generated virtual parameter set into
the bitstream using the entropy coding method.
[0086] Manner 2: the encoder sets the value of the syntax element
corresponding to the parameter set ID in the SH of the current
encoding slice as the ID of the generated parameter set, and writes
the ID of the generated parameter set into the bitstream using the
entropy coding method.
[0087] As an example implementation mode, the tool parameters
and/or the control parameters are depth information parameters, and
the tool parameters and/or the control parameters includes at least
one of: parameters for depth information digital presentation,
attribute parameters of camera imaging system and camera
arrangement manner related parameters.
[0088] An example embodiment provides a method for decoding using
parameter sets. FIG. 2 is a flowchart of a method for decoding
parameters according to an embodiment of the disclosure. As shown
in FIG. 2, the method includes the following Step S202 to Step
S206.
[0089] Step S202: a decoder generates a virtual parameter set,
wherein the virtual parameter set is a data structure which is
generated by loading information acquired from a bitstream into a
data element structure of an existing parameter set and/or a preset
data element structure and includes tool parameters and/or control
parameters.
[0090] Step S204: the decoder allocates an ID to the virtual
parameter set.
[0091] Step S206: the decoder activates the virtual parameter set
according to the ID of the virtual parameter set, and configures
tool parameters and/or control parameters for slice decoding
process according to parameters in the virtual parameter set.
[0092] By the steps, the decoder generates a virtual parameter set,
allocates an ID to the parameter set, activates the virtual
parameter set according to the ID, and configures tool parameters
and/or control parameters for the slice decoding process according
to parameters in the virtual parameter set, so that a flow of
determining decoding parameters by the decoder in a decoding
process can be simplified, and decoding efficiency is further
improved.
[0093] As an example implementation mode, in order to improve the
decoding efficiency, before Step S202, the decoder may also
determine that one or more types of preset tool parameters and/or
control parameters are able to be acquired from one or more
independent elements in the bitstream.
[0094] As an example implementation mode, in order to improve the
decoding efficiency, before Step S202, the decoder may also acquire
an ID of a parameter set directly and/or indirectly referred to by
a slice from the bitstream; and the decoder determines that values
of the IDs of the parameter sets directly and/or indirectly
referred to by the slice are out of a preset value range.
[0095] During implementation, the decoder may generate the virtual
parameter set in multiple implementation modes. For example: the
decoder generates the virtual parameter set by loading information
acquired from one or more independent elements of the bitstream
into a syntax structure of the existing parameter set or a preset
syntax structure, wherein the virtual parameter set includes all
and/or a part of information included in the one or more
independent elements in the bitstream. In an example embodiment,
the decoder may decompose the ID of the parameter set directly or
indirectly referred to by the slice into index numbers of the one
or more independent elements for constructing the virtual parameter
set according to the ID of the parameter set directly or indirectly
referred to by the slice; and the decoder acquires the information
from the one or more independent elements in the bitstream
according to the index numbers of the one or more independent
elements, and generates the virtual parameter set according to the
syntax structure of the existing parameter set or the preset syntax
structure.
[0096] In an example embodiment, in order to improve decoding
accuracy, the decoder may construct the virtual parameter set based
on all or a part of tool parameters and/or control parameters
included in one or more front independent elements according to
parsing order of the index numbers of multiple independent
elements.
[0097] In an example embodiment, the index numbers of the
independent elements are IDs of existing parameter sets.
[0098] In an example embodiment, the independent elements in the
bitstream are data elements divided by delimiters periodically
appearing in the bitstream. In an example embodiment, the data
elements are NAL units.
[0099] As an example implementation mode, the decoder may allocate
the ID to the virtual parameter set in one of manners as
follows.
[0100] Manner 1: the decoder allocates an ID reserved for the
virtual parameter set to the virtual parameter set. In an example
embodiment, the decoder allocates a reserved fixed numerical value
to the virtual parameter set as the ID of the virtual parameter
set.
[0101] Manner 2: the decoder allocates a numerical value out of a
preset range to the virtual parameter set as the ID of the virtual
parameter set. In an example embodiment, the decoder employs a
numerical value of a parameter set ID out of the preset range in
the bitstream of the slice as the ID of the virtual parameter
set.
[0102] As an example implementation mode, the method may further
include: the decoder activates an existing virtual parameter set.
In an example embodiment, the step may be implemented in a manner
as follows: the decoder activates a virtual parameter set
configured for current slice, which is generated before decoding
the current slice and has the same virtual parameter set ID; and
the decoder configures the tool parameters and/or control
parameters for the slice decoding process using parameters in the
activated virtual parameter set.
[0103] It should be noted that the steps shown by the flowchart in
the drawing can be executed in a computer system, such as a group
of computers, capable of executing an instruction, and moreover, a
logic sequence is shown in the flowchart, but the shown or
described steps can be executed in a sequence different from the
logic sequence under a certain condition.
[0104] In another embodiment, software for encoding using parameter
sets is also provided, which is configured to execute the technical
solutions described by the abovementioned embodiments and example
embodiments.
[0105] In another embodiment, a storage medium is also provided, in
which the software for encoding using parameter sets is stored,
wherein the storage medium includes, but not limited to: an optical
disk, a floppy disk, a hard disk, an erasable memory and the
like.
[0106] An embodiment of the disclosure provides a device for
encoding using parameter sets, which may be applied to an encoder.
The device for encoding using parameter sets may be configured to
implement the method for encoding using parameter sets and the
example implementation modes, that what has been described will not
be repeated, and components involved in the device for encoding
using parameter sets are described below. For example, a term
"component", used below, is a combination of software and/or
hardware for realizing preset functions. The systems and methods
described in the following embodiment are preferably implemented by
software, but the implementation of the systems and the methods
with hardware or the combination of software and hardware is also
possible and conceived.
[0107] FIG. 3 is a structure diagram of a device for encoding
parameters according to an embodiment of the disclosure. As shown
in FIG. 3, the device includes: a first determination component 32
and a first processing component 34. The structure is described
below in detail.
[0108] The first determination component 32 is configured to
determine parameter sets and/or virtual parameter sets for a slice,
wherein the virtual parameter set is a data structure which is
generated by loading information acquired from a bitstream into a
syntax structure of an existing parameter set and/or a preset
syntax structure and includes tool parameters and/or control
parameters; and the first processing component 34 is coupled with
the first determination component 32, and is configured to write
IDs of the parameter sets and/or virtual parameter sets determined
by the first determination component 32 into the bitstream.
[0109] FIG. 4 is an example structure diagram of a device for
encoding parameters according to an embodiment of the disclosure.
As shown in FIG. 4, the example structure diagram of the device for
encoding the parameters includes a first determination component 32
and a first processing component 34. The structure is described
below in detail.
[0110] The first determination component 32 includes:
[0111] a first judgment component 320, configured to judge whether
at least one of the following conditions meets or not: tool
parameters and/or control parameters for encoding current slice are
the same as tool parameters and/or control parameters of the
existing parameter set, the tool parameters and/or control
parameters for encoding the current slice are the same as tool
parameters and/or control parameters in an existing virtual
parameter set; a second determination component 321, coupled with
the first judgment component 320 and configured to, if a judgment
result of the first judgment component 320 is positive, determine
the existing parameter set which is determined by the first
judgment component to have the same tool parameters and/or control
parameters as the parameter set for the slice, and/or determine the
existing virtual parameter set which is determined by the first
judgment component to have the same tool parameters and/or control
parameters as the virtual parameter set for the slice; and a third
determination component 323, coupled with the first judgment
component 320 and configured to, if the judgment result of the
first judgment component 320 is negative, employ a generated
parameter set as the parameter set for the slice, and/or employ a
constructed virtual parameter set as the virtual parameter set for
the slice.
[0112] In an example embodiment, the first processing component 34
is configured to write an ID of the parameter set which is
determined by the first judgment component 322 to have the same
tool parameters and/or control parameters and/or an ID of the
virtual parameter set which is determined by the first judgment
component 320 to have the same tool parameters and/or control
parameters into one of the following bitstreams: an SH bitstream, a
bitstream including the parameter set with the same tool parameters
and/or control parameters and/or a bitstream including the virtual
parameter set with the same tool parameters and/or control
parameters.
[0113] In an example embodiment, the first processing component 34
includes:
[0114] a second judgment component 340, configured to identify that
the tool parameters and/or control parameters for the current
encoding slice are partially but not completely the same as the
tool parameters and/or control parameters of the parameter set; a
first setting component 341, configured to set a value of a syntax
element corresponding to the ID of the parameter set in an SH of
the current encoding slice as a first preset value; a second
processing component 342, configured to write the first preset
value into the bitstream using an entropy coding method; and/or a
second setting component 343, configured to set a value of a syntax
element corresponding to a parameter set ID of the parameter set
including the tool parameters and/or the control parameters as a
second preset value; a third processing component 344, configured
to write the second preset value into the bitstream using the
entropy coding method;
[0115] a third judgment component 345, configured to identify that
the tool parameters and/or control parameters for the current
encoding slice are completely different from the tool parameters
and/or control parameters of the parameter set; a first generation
component 346, coupled with the third judgment component 345 and
configured to generate a parameter set including the tool
parameters and/or control parameters for the current encoding
slice; a first allocation component 347, coupled with the first
generation component 346 and configured to allocate an ID to the
parameter set for the current encoding slice; a third setting
component 348, coupled with the first allocation component 347 and
configured to set the value of the syntax element corresponding to
the ID of the parameter set in the SH of the current encoding slice
to be the ID of the generated parameter set; and a fourth
processing component 349, coupled with the third setting component
348 and configured to write the ID of the generated parameter set
into the bitstream using the entropy coding method.
[0116] In an example embodiment, the first determination component
32 includes:
[0117] a fourth judgment component 323, configured to judge, by the
encoder, whether the tool parameters and/or control parameters for
the current encoding slice are partially but not completely the
same as the tool parameters and/or control parameters in the
parameter set or not, and a virtual parameter set with a tool
parameters and/or control parameters completely the same as the
tool parameters and/or control parameters for the current encoding
slice is able to be constructed or not; a fifth processing
component 324, coupled with the fourth judgment component 323 and
configured to, if a judgment result of the fourth judgment
component 323 is positive, construct, by the encoder, a virtual
parameter set based on data in the existing parameter set as the
virtual parameter set for the slice; a fourth determination
component 325, configured to determine the ID of the virtual
parameter set for the slice;
[0118] a second generation component 326, coupled with the fourth
judgment component 323 and configured to, if the judgment results
of the fourth judgment component 323 are negative, generate a
parameter set including the tool parameters and/or the control
parameters; and a second allocation component 327, coupled with the
second generation component 326 and configured to allocate an ID to
the generated parameter set.
[0119] In an example embodiment, the first processing component 34
includes:
[0120] a fourth setting component 350, configured to set the value
of the syntax element corresponding to the parameter set ID in the
SH of the current encoding slice as the ID of the generated virtual
parameter set; a fifth processing component 351, configured to
write the value into the bitstream using an entropy coding method;
and/or a fifth setting component 352, configured to set the value
of the syntax element corresponding to the parameter set ID in the
parameter set including the tool parameters and/or the control
parameters as the ID of the virtual parameter set; a sixth
processing component 353, configured to write the ID of the
generated virtual parameter set into the bitstream using the
entropy coding method; or
[0121] a sixth setting component 354, configured to set the value
of the syntax element corresponding to the parameter set ID in the
SH of the current encoding slice as the ID of the generated
parameter set; and a seventh processing component 355, coupled with
the sixth setting component 354 and configured to write the ID of
the generated parameter set into the bitstream by virtue of the
entropy coding method.
[0122] In another embodiment, software for decoding using parameter
sets is also provided, which is configured to execute the technical
solutions described in the abovementioned embodiments and example
embodiments.
[0123] In another embodiment, a storage medium is also provided, in
which the software for decoding using a parameter set is stored,
wherein the storage medium includes, but not limited to: an optical
disk, a floppy disk, a hard disk, an erasable memory and the
like.
[0124] An embodiment of the disclosure provides a device for
decoding using parameter sets. The device for decoding using
parameter sets may be configured to implement the method for
decoding using parameter sets and the example implementation modes,
that what has been described will not be repeated, and components
involved in the device for decoding using parameter sets are
described below. For example, a term "component", used below, is a
combination of software and/or hardware for realizing preset
functions. The system and method described in the following
embodiment are preferably implemented by software, but the
implementation of the system and the method with hardware or the
combination of software and hardware is also possible and
conceived.
[0125] FIG. 5 is a structure diagram of a device for decoding
parameters according to an embodiment of the disclosure. As shown
in FIG. 5, the device includes: a third generation component 52, a
third allocation component 54, a first activation component 56 and
a first decoding component 58. The structure is described below in
detail.
[0126] The third generation component 52 is configured to generate
virtual parameter sets, wherein the virtual parameter set is a data
structure which is generated by loading information acquired from a
bitstream into a data element structure of an existing parameter
set and/or a preset data element structure and includes tool
parameters and/or control parameters; the third allocation
component 54 is coupled with the third generation component 52, and
is configured to allocate an ID to the virtual parameter set; the
first activation component 56 is coupled with the third allocation
component 54, and is configured to activate the virtual parameter
set according to the ID, which is allocated by the third allocation
component 54, of the virtual parameter set; and the first decoding
component 58 is coupled with the first activation component 56, and
is configured to configure tool parameters and/or control
parameters for slice decoding process according to parameters in
the virtual parameter set.
[0127] FIG. 6 is an example structure diagram of a device for
decoding parameters according to an embodiment of the disclosure.
As shown in FIG. 6, the device further includes: a fifth judgment
component 62, an acquisition component 64 and a sixth judgment
component 66. The third generation component 52 includes: a
decomposition component 522 and a fourth generation component 524.
The third allocation component 54 includes: a fourth allocation
component 542 and a fifth allocation component 544. The device
further includes: a second activation component 68, wherein the
second activation component 68 includes: a third activation
component 682 and a second decoding component 684. The structure is
described below in detail.
[0128] In an example embodiment, the device further includes: the
fifth judgment component 62, configured to determine that one or
more types of preset tool parameters and/or control parameters are
able to be acquired from one or more independent elements in the
bitstream.
[0129] In an example embodiment, the device further includes: the
acquisition component 64, configured to acquire an IDs of parameter
sets directly and/or indirectly referred to by a slice from the
bitstream; and the sixth judgment component 66, coupled with the
acquisition component 64 and configured to determine that values of
the IDs, which are acquired by the acquisition component 64, of the
parameter sets directly and/or indirectly referred to by the slice
are out of a preset value range.
[0130] In an example embodiment, the third generation component 52
is configured to generate the virtual parameter set by loading
information acquired from one or more independent elements of the
bitstream into a syntax structure of the existing parameter set or
a preset syntax structure, wherein the virtual parameter set
includes all and/or a part of information included in the one or
more independent elements in the bitstream.
[0131] The third generation component 52 includes: the
decomposition component 522, configured to decompose the ID of the
parameter set directly or indirectly referred to by the slice into
index numbers of the one or more independent elements for
constructing the virtual parameter set according to the ID of the
parameter set directly or indirectly referred to by the slice; and
the fourth generation component 524, coupled with the decomposition
component 522 and configured to acquire the information from the
one or more independent elements in the bitstream according to the
index numbers of the one or more independent elements, and generate
the virtual parameter set according to the syntax structure of the
existing parameter set or the preset syntax structure.
[0132] In an example embodiment, the fourth generation component
524 is configured to construct the virtual parameter set based on
all or a part of tool parameters and/or control parameters included
in one or more front independent elements according to a parsing
order of the index numbers of multiple independent elements.
[0133] In an example embodiment, the third allocation component 54
includes: the fourth allocation component 542, configured to
allocate an ID reserved for the virtual parameter set to the
virtual parameter set. In an example embodiment, the fourth
allocation component 542 is configured to allocate a reserved fixed
numerical value to the virtual parameter set as the ID of the
virtual parameter set.
[0134] In an example embodiment, the third allocation component 54
includes: the fifth allocation component 544, configured to
allocate a numerical value out of a preset range to the virtual
parameter set as the ID of the virtual parameter set. In an example
embodiment, the fifth allocation component 544 is configured to
employ, by the decoder, a numerical value of a parameter set ID out
of the preset range in the bitstream of the slice as the ID of the
virtual parameter set.
[0135] In an example embodiment, the device further includes: the
second activation component 68, configured to activate an existing
virtual parameter set.
[0136] In an example embodiment, the second activation component 68
includes: the third activation component 682, configured to
activate virtual parameter sets configured for current slice, which
is generated before decoding the current slice and has the same
virtual parameter set ID; and the second decoding component 684,
coupled with the third activation component 682 and configured to
configure the tool parameters and/or control parameters for the
slice decoding process using parameters in the activated virtual
parameter set.
[0137] An embodiment of the disclosure provides electronic
equipment. FIG. 7 is a structure diagram of electronic equipment
according to an embodiment of the disclosure. As shown in FIG. 7,
the electronic equipment includes a device 2 (as shown in FIG. 3 or
4) for encoding using parameter sets and/or a device 4 (as shown in
FIG. 5 or 6) for decoding using parameter sets.
[0138] Description is given below with reference to example
embodiments, and the following example embodiments combine the
abovementioned embodiments and example embodiments.
Example Embodiment 1
[0139] The example embodiment provides a method for decoding using
virtual parameter sets. FIG. 8 is a flowchart of a method for
decoding according to an embodiment of the disclosure. As shown in
FIG. 8, the method includes the following Step 802 to Step 806.
[0140] Step 802: a decoder generates a virtual parameter set
including a parameter set ID.
[0141] Step 804: the decoder directly or indirectly refers to the
virtual parameter set according to the parameter set ID.
[0142] Step 806: the decoder activates the virtual parameter set
following the method consistent with the method for activating a
conventional parameter set, and acquires parameters required by
current slice decoding process from the virtual parameter set.
Example Embodiment 2
[0143] The example embodiment provides a method for encoding using
virtual parameter sets. FIG. 9 is a flowchart of a method for
encoding according to an embodiment of the disclosure. As shown in
FIG. 9, the method includes the following Step 902 to Step 906.
[0144] Step 902: an encoder determines parameters for slice
encoding process.
[0145] Step 904: the encoder determines parameter sets and/or
virtual parameter sets for current slice based on coded parameter
sets and/or virtual parameter sets.
[0146] Step 906: the encoder writes IDs of the parameter sets
and/or virtual parameter sets into a bitstream.
[0147] In an example embodiment, in the embodiment, existing
information in a bitstream may be combined to generate a virtual
parameter set including a parameter set ID according to a syntax
structure of a conventional parameter set or an independently
designed syntax structure.
[0148] In an example embodiment, in the bitstream, data of the
parameter set are located in one independent NAL unit with a
specific type ID, but data of the virtual parameter set may be from
one or more different types of NAL units.
[0149] In an example embodiment, a method for operating the virtual
parameter set at slice layer is the same as the method for
operating an ordinary parameter set. The slice layer directly or
indirectly refers to the virtual parameter sets according to the
parameter set IDs. When a certain virtual parameter set is referred
to, the virtual parameter set is activated by the method in the
same way as that for the ordinary parameter set, and parameters
required by current slice decoding process are acquired from the
virtual parameter set.
[0150] It should be noted that with the use of the virtual
parameter sets, special flows are not required to be set for
certain specific parameter set IDs in a process of referring to the
parameter set at slice layer and parameter set activation process;
additional flags are not required to be introduced at slice layer
with special conditional processing flows; and when activating
ordinary parameter sets and/or virtual parameter sets, the decoder
can clearly identify the decoding processes to which the data in
parameter sets are applied, without referencing to the syntax
elements following the parameter set IDs at slice layer in parsing
order to determine and execute the corresponding additional
judgments and operations.
[0151] An encoder implementation method in each following
embodiment is only one of possible encoder implementation methods
under the embodiment, and any encoder capable of generating a
bitstream meeting a requirement of the encoding process in the
embodiment may implement an encoder implementation method in the
embodiment.
Example Embodiment 3
[0152] A method for organizing a subset SPS, a DPS and SH bitstream
in the example embodiment is the same as a conventional 3D-AVC
method.
[0153] FIG. 10 is a flowchart of a method for decoding according to
an example embodiment of the disclosure. As shown in FIG. 10, the
method for decoding in the embodiment includes the following Step
S1001 to Step S1006.
[0154] Step S1001: a decoder parses an SH, and determines an ID of
a subset SPS referred to by a slice.
[0155] The decoder reads a bitstream of the SH from a received
bitstream, and parses pic_parameter_set_id of a Picture Parameter
Set (PPS) referred to by a current slice using an entropy decoding
method corresponding to ue(v).
[0156] The decoder sets a PPS with its ID value equal to
pic_parameter_set_id to be "active". The decoder parses a bitstream
of the PPS, and parses seq_parameter_set_id of a subset SPS
referred to by the PPS using the entropy decoding method
corresponding to ue(v).
[0157] The decoder sets a value of seq_parameter_set_id to be a
value of the ID of the subset SPS referred to by the current
slice.
[0158] Step S1002: the decoder parses a subset SPS corresponding to
the ID, and activates the parameter set.
[0159] Step S1003: the decoder judges whether the subset SPS
includes DPs or not. If the subset SPS includes DPs, Step S1004 is
executed; otherwise, Step S1005 is executed.
[0160] Step S1004: the decoder generates a virtual parameter set,
and executes Step S1005.
[0161] The decoder constructs a virtual DPS according to a DPS
syntax element organization structure and method based on the DPs
in the activated subset SPS, and sets an ID of the virtual DPS to
be 0.
[0162] Alternatively, the decoder may construct the virtual DPS
according to a preset syntax element organization method based on
the DPs in the activated subset SPS, and sets the ID of the virtual
DPS to be 0.
[0163] The preset syntax element organization method may be any
representation method for DP data, such as a representation method
for directly listing ZFar, ZNear and camera parameters or a
representation method of splitting the ZFar, the ZNear and the
camera parameters into integer parts and decimal parts.
[0164] Step S1005: the decoder continues parsing other syntax
elements in the SH. If a slice layer refers to the DPS through the
DPS ID, the corresponding DPS (including the virtual DPS) is parsed
and activated.
[0165] When the decoder determines that DRWP and/or VSP are used in
decoding the current slice, the decoder refers to the DPS via the
DPS ID in the decoding process.
[0166] The decoder parses the dps_id of the DPS referred to by the
current slice using the entropy decoding method corresponding to
ue(v).
[0167] The decoder sets a DPS or virtual DPS with its ID value
equal to dps_id to be "active", and acquires DPs used in decoding
of the current slice from the currently activated DPS or virtual
DPS using the conventional data processing method for an activated
parameter set in 3D-AVC.
[0168] Step S1006: the decoder continues parsing the syntax
elements in the SH.
[0169] FIG. 11 is a flowchart of a method for encoding according to
an example embodiment of the disclosure. As shown in FIG. 11, the
method for encoding in the embodiment includes the following Step
S1101 to Step S1110.
[0170] Step S1101: an encoder determines DPs to be written into a
subset SPS, and writes the DPs into the subset SPS.
[0171] For a non-real time application (such as storage playing),
the encoder scans DPs required by the entire sequence, employs the
DPs for most frames as the DPs to be written into the subset SPS,
and writes the DPs into the subset SPS according to an organization
method and entropy coding method for syntax elements related to
these DPs in the subset SPS.
[0172] For an application tolerant to a certain time delay, the
encoder starts scanning from a first frame of a sequence to a
specified moment (such as a time delay upper limit), employs DPs
for most frames as the DPs to be written into the subset SPS, and
writes the DPs into the subset SPS according to the organization
method and entropy coding method for the syntax elements related to
these DPs in the subset SPS.
[0173] For a low delay application (such as a video conference),
the encoder directly employs DPs of the first frame of the sequence
as the DPs to be written into the subset SPS, and writes the DPs
into the subset SPS according to the organization method and
entropy coding method for the syntax elements related to these DPs
in the subset SPS.
[0174] Step S1102: the encoder determines DPs used for an access
unit (AU) where current slice is located.
[0175] The encoder may directly obtain camera parameters at the
sampling time instant of the picture containing the current slice
in current AU from an external control element.
[0176] If depth information is directly acquired from a depth
camera, the encoder may acquire parameter values such as ZFar and
ZNear at the sampling time instant of the picture containing the
current slice in the current AU from a depth information processing
element of the depth camera or a depth information processing
element of a system.
[0177] If the depth information is estimated from 3DV video and
information, the encoder can acquire the parameter values such as
ZFar and ZNear at the sampling time instant of the picture
containing the current slice in the current AU from a 3DV
preprocessing element of the system.
[0178] The encoder acquires information such as ZFar, ZNear and the
camera parameters from system equipment, and employs the
information as the DPs for the AU containing the current slice.
[0179] Step S1103: the encoder judges whether the DPs for the
current AU are the same as the DPs in the subset SPS or not. If the
DPs for the current AU are the same as the DPs in the subset SPS,
Step S1104 is executed; otherwise, Step S1105 is executed.
[0180] Step S1104: the encoder sets values of syntax elements
dps_id in all SHs of the slices included in the current AU to be 0,
and writes the values into bitstream using an entropy coding method
corresponding to ue(v). Step S1106 is executed.
[0181] Step S1105: the encoder determines a DPS for the slice in
the current AU, sets a value of a syntax element dps_id in the SH
to be an ID value of the used DPS, and writes the value into the
bitstream. Step S1106 is executed.
[0182] If the DPs for the current AU are the same as the DPs
included in a certain coded DPS, the value of the syntax element
dps_id in the SH is set to be the ID value of the DPS, and the
value of dps_id is written into the bitstream using the entropy
coding method corresponding to ue(v).
[0183] If the DPs for the current AU are different from DPs
included in existing coded DPSs, a new DPS is generated using the
method in 3D-AVC. DP information is written into the DPS, and an ID
value is allocated to the DPS. The encoder sets the value of the
syntax element dps_id in the SH to be the ID value of the DPS, and
the value of dps_id is written into the bitstream using the entropy
coding method corresponding to ue(v).
[0184] Step S1106: the encoder continues encoding the slice
included in the current AU.
Example Embodiment 4
[0185] The syntax structures for subset SPS, DPS and SH in this
example embodiment are the same as those in 3D-AVC method.
[0186] FIG. 12 is a flowchart of a method for decoding according to
an example embodiment of the disclosure. As shown in FIG. 12, the
method for decoding in the example embodiment includes the
following Step S1201 to Step S1206.
[0187] Step S1201: a decoder parses SH, and determines an ID of a
subset SPS referred to by a slice.
[0188] The decoder reads a bitstream of the SH from a received
bitstream, and parses pic_parameter_set_id of a PPS referred to by
current slice using an entropy decoding method corresponding to
ue(v).
[0189] The decoder sets a PPS with its ID value equal to
pic_parameter_set_id to be "active". The decoder parses bitstream
of the PPS, and parses seq_parameter_set_id of a subset SPS
referred to by the PPS using the entropy decoding method
corresponding to ue(v).
[0190] The decoder sets a value of seq_parameter_set_id to be a
value of the ID of the subset SPS referred to by the current
slice.
[0191] Step S1202: the decoder parses a subset SPS corresponding to
the ID, and activates the parameter set.
[0192] Step S1203: the decoder judges whether the subset SPS
includes DPs or not. If the subset SPS includes DPs, Step S1204 is
executed; otherwise, Step S1205 is executed.
[0193] Step S1204: the decoder generates a virtual parameter set,
and executes Step S1205.
[0194] The decoder constructs a virtual DPS according to a DPS
syntax element organization structure and method based on the DPs
in the activated subset SPS, and sets an ID of the virtual DPS to
be 0.
[0195] Alternatively, the decoder may construct the virtual DPS
according to a preset syntax element organization method based on
the DPs in the activated subset SPS, and sets the ID of the virtual
DPS to be 0.
[0196] The preset syntax element organization method may be any
representation method for DP data, such as a representation method
for directly listing ZFar, ZNear and camera parameters or a
representation method of splitting the ZFar, the ZNear and the
camera parameter into integer parts and decimal parts.
[0197] Step S1205: the decoder continues parsing the SH. If a slice
layer refers to the DPS through the DPS ID, the syntax element
dps_id is parsed.
[0198] When the decoder determines that DRWP and/or VSP are used in
decoding the current slice, the decoder determines to refer to the
DPS via the DPS ID in the decoding process.
[0199] The decoder parses the dps_id of the DPS referred to by the
current slice using the entropy decoding method corresponding to
ue(v).
[0200] Step S1206: the decoder judges whether the value of dps_id
is greater than a maximum allowable value DPS_ID_MAX of the DPS ID
in the bitstream or not. If the value of dps_id is greater than
DPS_ID_MAX, Step S1207 is executed; otherwise, Step S1209 is
executed.
[0201] A value of DPS_ID_MAX is positive integer power of 2.
[0202] The value of DPS_ID_MAX may be a fixed value, and different
values can be set for combinations of different Profiles and
different Levels in Profile/Level, or the value of DPS_ID_MAX is
coded and transmitted in another parameter set (such as subset
SPS).
[0203] Step S1207: the encoder converts dps_id into multiple DPS
IDs.
[0204] The decoder assigns the value of dps_id to a temporary
variable tempDpsId. The decoder converts a numerical value
corresponding to tempDpsId into a binary value, reads log
2(DPS_ID_MAX) bits from Least Significant Bit (LSB) to Most
Significant Bit (MSB), and employs a decimal numerical value
corresponding to these bits as dpsId[0]. Data obtained by removing
the log 2(DPS_ID_MAX) bits from tempDpsId is reassigned to
tempDpsId.
[0205] If a value of tempDpsId is smaller than DPS_ID_MAX, its
decimal numerical value is employed as dpsId[1]. On the contrary,
if the value of tempDpsId is still greater than DPS_ID_MAX, the
above operation is repeated, and the decoder converts the numerical
value corresponding to tempDpsId into binary value, reads log
2(DPS_ID_MAX) bits from LSB to MSB, and employs a decimal numerical
value corresponding to the bits as dpsId[1]. The decoder reassigns
data obtained by removing the log 2(DPS_ID_MAX) bits from tempDpsId
to tempDpsId.
[0206] The decoder can obtain multiple DPS ID values, i.e.
dpsId[0], dpsId[1], . . . , dpsId[n-1], by decomposing dps_id by
repeating the above flow, and the data of the corresponding DPS is
stored in dpsContent[dpsId[i]], wherein i is 0, 1, . . . , n-1.
[0207] Step S1208: the decoder constructs a virtual DPS using
multiple DPSs, and sets an ID value of the virtual DPS to be equal
to dps_id. Step S1209 is executed.
[0208] The decoder constructs the virtual DPS according to the DPS
syntax structure using the DPs in the activated subset SPS, and
sets the ID of this virtual DPS to be 0.
[0209] Alternatively, the decoder may construct the virtual DPS
according to the preset syntax structure using the DPs in the
activated subset SPS, and sets the ID of the virtual DPS to be
0.
[0210] The preset syntax element organization method may be any
representation method for DP data, such as a representation method
for directly listing ZFar, ZNear and camera parameters or a
representation method of splitting the ZFar, the ZNear and the
camera parameter into integer parts and decimal parts.
[0211] The decoder allocates a storage space dpsContent[dps_id] to
the virtual DPS, and initializes the storage space as follows: each
data parameter in the DPS does not exist, that is, a flag of each
data parameter is set to be 0.
[0212] The decoder determines data in the virtual DPS using the
pseudo code as follows:
[0213] for (i=0; i<n; i++) [0214] mergeDps(dpsContent[dps_id],
dpsContent[dpsId[i]]); wherein mergeDps(dpsA, dpsB) functions as
follows: if a value of a flag indicating whether a certain data
parameter in dpsA exists or not is 0, the flag for the data
parameter and value of the data parameter in dpsA are set to be
equal to the counterpart flag and the counterpart data parameter in
dpsB.
[0215] Step S1209: the decoder sets the DPS or virtual DPS with its
ID value equal to dps_id to be "active", and acquires the DPs for
the decoding of the current slice from the currently activated DPS
or virtual DPS using the conventional data processing method for
the activated parameter set in 3D-AVC.
[0216] Step S1210: the decoder continues parsing syntax elements in
the SH.
[0217] Particularly, the following method may be used by the
decoder. For Step S1206, the decoder judges whether the value of
dps_id is greater than the maximum admissible value DPS_ID_MAX of
the DPS ID in the bitstream or not, and if the judgment result is
positive and the decoder has generated the virtual parameter set of
which the ID value is equal to dps_id before decoding the current
slice, the decoder may skip Step S1207 and Step S1208, and directly
activate the generated virtual parameter set with its ID value
equal to dps_id.
[0218] FIG. 13 is a second flowchart of a method for encoding
according to an example embodiment of the disclosure. As shown in
FIG. 13, the method for encoding in the embodiment of the
disclosure includes the following Step S1301 to Step S1306.
[0219] Step S1301: an encoder determines DPs to be written into a
subset SPS, and writes the DPs into the subset SPS.
[0220] For a non-real time application (such as storage playing),
the encoder scans DPs required by the entire sequence, employs the
DPs for most frames as the DPs to be written into the subset SPS,
and writes the DPs into the subset SPS according to an organization
method and entropy coding method for syntax elements related to
these DPs in the subset SPS.
[0221] For an application tolerant to a certain time delay, the
encoder starts scanning from the first frame of a sequence to a
specified moment (such as a time delay upper limit), employs DPs
for most frames as the DPs to be written into the subset SPS, and
writes the DPs into the subset SPS according to the organization
method and entropy coding method for the syntax elements related to
these DPs in the subset SPS.
[0222] For a low delay application (such as a video conference),
the encoder directly employs DPs of the first frame of the sequence
as the DPs to be written into the subset SPS, and writes the DPs
into the subset SPS according to the organization method and
entropy coding method for the syntax elements related to these DPs
in the subset SPS.
[0223] Step S1302: the encoder determines DPs used for an AU where
a current encoding slice is located.
[0224] The encoder may directly obtain camera parameters at the
sampling time instant of the picture containing the current slice
in current AU from an external control element.
[0225] If depth information is directly acquired from a depth
camera, the encoder may acquire parameter values such as ZFar and
ZNear at the sampling time instant of the picture containing the
current slice in the current AU from a depth information processing
element of the depth camera or a depth information processing
element of a system.
[0226] If the depth information is estimated from 3DV video and
information, the encoder can acquire the parameter values such as
ZFar and ZNear at the sampling time instant of the picture
containing the current slice in the current AU from a 3DV
preprocessing element of the system.
[0227] The encoder acquires information such as ZFar, ZNear and the
camera parameters from system equipment, and employs the
information as the DPs for the AU containing the current slice.
[0228] Step S1303: the encoder judges whether the DPs for the
current AU are the same as the DPs in the subset SPS or not. If the
DPs for the current AU are the same as the DPs in the subset SPS,
Step S1304 is executed; otherwise, Step S1305 is executed.
[0229] Step S1304: the encoder sets values of syntax elements
dps_id in all SHs of the slices in the current AU to be 0, and
writes the values into a bitstream using an entropy coding method
corresponding to ue(v). Step S1306 is executed.
[0230] Step S1305: the encoder determines a DPS for the slice in
the current AU, sets a value of syntax element dps_id in the SH to
be an ID value of the used DPS, and writes the value into the
bitstream. Step S1306 is executed.
[0231] A determination process for dps_id in Step S1305 may be
implemented under three conditions:
[0232] Condition 1:
[0233] If the currently used DPs are the same as the DPs included
in a certain coded DPS or virtual DPS, the encoder sets the values
of the syntax elements dps_id in all the SHs to be the ID value of
the DPS or virtual DPS, and writes the values of dps_id into the
bitstream using the entropy coding method corresponding to
ue(v).
[0234] Condition 2:
[0235] If each data parameter in the currently used DPs is the same
as corresponding data parameters of DPSs and virtual DPSs, of which
IDs are smaller than DPS_ID_MAX, respectively (it is supposed that
there are totally n DPSs or virtual DPSs), the IDs of the DPSs and
the virtual DPSs are recorded respectively, and are stored in
dpsId[0], dpsId[1], . . . , dpsId[n-1], and the corresponding data
parameters in the DPSs and the virtual DPSs are stored in
dpsContent[dpsId[i]], wherein i is 0, 1, . . . , n-1; and the value
of DPS_ID_MAX is positive integer power of 2.
[0236] The value of DPS_ID_MAX may be a fixed value, and different
values may be set for combinations of different Profiles and
different Levels in Profile/Level, or the value of DPS_ID_MAX is
coded and transmitted in another parameter set (such as subset
SPS).
[0237] The encoder adjusts the storage order of the IDs of the DPSs
and the virtual DPSs in an array dpsId[i] (wherein, i is 0, 1, . .
. , n-1) until the data parameters which can be obtained using the
following pseudo code in virtualDps are the same as the currently
used DPs. In the pseudo code, virtualDps is initialized in a way
that each data parameter in the DPS does not exist, that is, a flag
corresponding to each data parameter is set to be 0.
[0238] for (i=0; i<n; i++) [0239] mergeDps(virtualDps,
dpsContent[dpsId[i]]); wherein mergeDps(dpsA, dpsB) functions as
follows: if a value of a flag indicating whether a certain data
parameter in dpsA exists or not is 0, the flag for the data
parameter and value of the data parameter in dpsA are set to be
equal to the counterpart flag and the counterpart data parameter in
dpsB.
[0240] The encoder calculates the value of dps_id using the
following pseudo code:
TABLE-US-00001 currDpsld = dpsld[ 0 ]; for ( i = 1; i < n; i++ )
{ currDpsld = currDpsld << log2(MAX_DPS_ID); currDpsld +=
dpsld[ i ]; }
[0241] The encoder sets the values of the syntax elements dps_id in
all the SHs of the slices in the current AU to be currDpsId, and
writes the values into the bitstream using the entropy coding
method corresponding to ue(v).
[0242] Condition 3
[0243] If the currently used DPs are different from DP data in any
coded DPS and virtual DPS, or the Condition 2 is met but the
encoder considers the method used under the condition 2 is
relatively complex (the number of the existing DPSs used in
generating the virtual DPS for the current AU is controlled in
consideration of error resistance) according to the encoder
optimization rules, the encoder generates a new DPS for the
currently used DPs, allocates an ID to the DPS, a value of the ID
being more than 0 and smaller than MAX_DPS_ID, and assigns the
value to the syntax elements dps_id of all the SHs of the slices in
the current AU.
[0244] The encoder encodes the currently used DPs using the
generated DPS, and writes the value of dps_id into the bitstream
using the entropy coding method corresponding to ue(v).
[0245] Step S1306: the encoder continues encoding the slice
included in the current AU.
Example Embodiment 5
[0246] The embodiment provides electronic equipment, which is
capable of encoding a 3DV signal using the encoder implementation
methods in the abovementioned embodiments and output a
bitstream.
[0247] The electronic equipment can parse the bitstream to obtain
DPs used in decoding process to recover the 3DV signal using the
methods for decoder implementation in the abovementioned
embodiments.
[0248] The electronic equipments of the embodiment may be the
equipment generating bitstreams and/or the equipment receiving and
rendering bitstreams in video communication application, such as a
mobile phone, a computer, a server, a set-top box, a portable
mobile terminal, a digital camera and television broadcasting
system equipments.
[0249] According to the embodiments, the methods and devices for
encoding and decoding using parameter sets, and the electronic
equipment are provided, and data is coded and decoded using the
virtual parameter sets, so that the problem of relatively complex
flows of methods for encoding and decoding using parameter sets in
the related art is solved, and the effect of improving encoding and
decoding efficiency is further achieved. It should be noted that
the technical effects are not peculiar to all of the abovementioned
embodiments, and some technical effects can be achieved by certain
example implementation modes.
[0250] Obviously, those skilled in the art should know that each
component or step of the disclosure can be implemented by a
universal computing device, and the components or steps can be
concentrated on a single computing device or distributed on a
network formed by a plurality of computing devices, and can
optionally be implemented by programmable codes executable for the
computing devices, so that the components or steps can be stored in
a storage device for execution with the computing devices, or can
form each integrated circuit component, or multiple components or
steps therein can form a single integrated circuit component for
implementation. As a consequence, the disclosure is not limited to
any specific hardware and software combination.
[0251] The above is only the example embodiment of the disclosure
and not intended to limit the disclosure, and for those skilled in
the art, the disclosure may have various modifications and
variations. Any modifications, equivalent replacements,
improvements and the like within the principle of the disclosure
shall fall within the scope of protection defined by the appended
claims of the disclosure.
* * * * *