KR960012741A - Apparatus and method for encoding and decoding data - Google Patents

Abstract

An apparatus and method for compressing and restoring data are described. The present invention provides an encoder in a compression system having a decoder for decoding information generated by an encoder. The encoder according to the present invention includes a coder for producing codeword information in response to data. The coder also includes a rearrangement device for generating a coded data string in response to codeword information from the coder. The rearrangement apparatus comprises: an execution coefficient rearranging apparatus for arranging code words in decoding order and a bit pack apparatus for merging a variable length code word into a fixed length interleaver and outputting the fixed length interleaver in the order requested by the decoder. Equipped.

Description

Apparatus and method for encoding and decoding data

As this is a public information case, the full text was not included.

3 is an exemplary diagram illustrating a non-interleved code string according to the present invention.

4 is an exemplary diagram illustrating one embodiment of an interleaved code string as derived from an exemplary data set.

5 is an embodiment of a bit string generator of a probability estimator for an R coder according to the present invention.

6 is a block diagram of one embodiment of an encoder of the present invention.

7 is a block diagram of one embodiment of a bit generator of the present invention.

Claims (121)

A method of encoding a data string, the method comprising: generating codeword information representing a data string in response to the data string, wherein the codeword information is composed of a plurality of codewords and is processed in parallel; A multiword is generated from the data in the column; Generating coded data in response to the codeword information, wherein the generating step includes a plurality of codewords in the codeword information output so that the order of the codewords to be output is the start of a portion of the data string indicated by each codeword. It includes; Data stream encoding method comprising a. 2. The method of claim 1, wherein the method outputs each of a plurality of codewords at the beginning of each execution. 2. The method of claim 1, wherein generating the encoded data comprises combining a variable length codeword into a fixed length data structure. 4. The method of claim 3, wherein each fixed length data structure comprises an interleaved language. The data string encoding method according to claim 1, wherein the method comprises the step of outputting encoded data in which codewords are arranged in a decoding order. 2. The data string encoding method according to claim 1, wherein said method comprises the step of ordering codewords. The method of claim 1, wherein the generating of the codeword information comprises generating a probability state of a codeword, selecting a bit generation code based on the probability state, and obtaining a continuous coefficient associated with a probability class. And accessing the memory in order to obtain the data string code. An encoding system for encoding a data string, the encoding system having a codeword including codeword information and an encoder connected to receive the data string to generate a multiple codeword generated by the encoder from data processed in parallel. A codeword generated by the coder in order of a decoder, in order to generate coded data in response to codeword information, and a sequence of the output codewords indicated by each codeword. An encoding system for encoding a data string, characterized by comprising a rearrangement unit based on a portion. 9. The encoding system according to claim 8, wherein said rearranging apparatus stores said codeword in a manner sufficient to indicate a codeword size. 10. The encoding system according to claim 9, wherein the encoding system rearranges 1N codewords so that an optimal signal "1" bit represents the length of each codeword. 9. The apparatus of claim 8, wherein the rearrangement apparatus comprises at least one execution coefficient rearrangement apparatus for generating each of the plurality of codewords in the codeword information at the beginning of each execution, and a variable length codeword as a fixed length data structure. And at least one bead pack device to be combined. 12. The coding system according to claim 11, wherein each fixed length data structure has an interleaved language. 9. The encoding system according to claim 8, wherein the rearrangement coder is arranged. The encoding system according to claim 13, wherein the encoding system comprises a memory connected to a rearranged device for storing codewords. 10. The apparatus of claim 8, wherein the encoder comprises a context model, a probability estimator connected to the context model, and a bit generator connected to the probability estimator to generate a codeword in response to a data sequence. An encoding system for encoding a column. 16. A bit according to claim 15, wherein said encoder has a memory for storing a plurality of execution coefficients, and said memory outputs a portion of codeword information from a probability device for providing one of a plurality of execution coefficients using a probability class. An encoding system for encoding a data string characterized by being approached by a generator. 16. The apparatus of claim 15, wherein the bit generator structure comprises: a bit generator for providing codeword information in response to an index and an MPS / LPS indication; a memory coupled to provide a performance factor to a bat generator; And a bit generation based on data obtained by reading the memory and reading the memory. 18. The codeword output according to claim 17, wherein the codeword information is a first signal indicating whether the MPS / LPS indication constitutes the start of execution, a second signal indicating whether the MPS / LPS indication constitutes the end of execution, and a codeword output. And an encoding system for encoding a data string. 12. The data string as claimed in claim 11, wherein the bit pack logic arranges the interleaved words in each interleaved of each string to generate an encoded data string such as an interleaved string arranged according to the Nth previous codeword. An encoding system for encoding the code. 12. The encoding system according to claim 11, wherein the rearrangement device comprises a snooper decoder for selecting an interleaved language output as a code string. 21. The apparatus of claim 20, wherein the rearrangement apparatus comprises a plurality of execution coefficient rearranging apparatuses connected to the plurality of bit pack apparatuses, each of the plurality of bit pack apparatuses to generate an interleaved language, and the snoop decoder An encoding system for encoding a data string, wherein an insertion word is selected from a plurality of interleaves outputted as a column. 12. The encoding system according to claim 11, wherein the codeword information includes a TIME STAMP and logic for outputting an interleaved based on a TIME STAMP associated with a rearrangement apparatus. 23. The apparatus according to claim 22, wherein said rearranging device includes a plurality of execution coefficient rearranging devices connected to a plurality of bit pack devices and is caused to be output based on a time stamp associated with said interleaving due to said logic. An encoding system for encoding a data string. 24. The encoding system of claim 23, wherein the interleaved language is output based on the oldest TIME STAMP. 12. The encoding method according to claim 11, wherein a single queue provides codewords to a plurality of bitpack devices, and the interleaved words are output by the plurality of bitpack devices as part of a code string. system. 26. The encoding system of claim 25, wherein the single queue includes a single execution coefficient rearrangement device, and the logic determines a next interleaved language for output as a code string. 12. The encoding system according to claim 11, wherein the single queue provides a codeword to a single bit pack device. An encoding system for use in a compression system having a decoder for decoding information generated by an encoder, the encoding system being connected to an encoder and a coder for producing codeword information in response to the data, A rearrangement apparatus for generating a coded data sequence as a response, an execution coefficient rearrangement apparatus for placing each codeword at the beginning of data corresponding to the rearrangement apparatus, and a codeword of various lengths into a plurality of fixed-length interleaves And a bit pack device coupled to receive codewords from the execution coefficient rearranging device for outputting a plurality of fixed length interleaved in the order required by the decoder. 29. The coding system according to claim 28, wherein said rearrangement device comprises a memory for storing code words during rearrangement. 29. The encoding system of claim 28, wherein the encoder comprises a context module, a probability estimator connected to the context module, and a bit string generator connected to the probability estimator. 31. The apparatus of claim 30, wherein the execution coefficient rearrangement apparatus comprises a first memory for storing a codeword, a first indicator for designating an address as a queue in a second memory, and a second indicator. Is the first entry indicated as the output of the first memory, and the second indicator points to the second entry indicated as the next possible and unallocated storage value in the first memory. 32. The encoding system according to claim 31, wherein the encoding system comprises a pointer memory for storing address information corresponding to a position currently displayed in a first memory for storing codewords for each index. 33. The coding system of claim 32, wherein each index represents a probability class. 33. The coding system of claim 32, wherein each index represents at least one context. 29. The apparatus of claim 28, wherein the rearrangement apparatus comprises: a codeword memory queue for storing codewords, a head pointer for representing at least one codeword for output, and a codeword for a codeword representation for at least a memory location. And a mail pointer for inserting the code. 36. The codeword of claim 35, wherein each codeword entry in a codeword memory queue includes a valid indication, wherein a codeword indicates that the head pointer indicates an address of a codeword and a valid indication for a codeword indicates its validity. The coding system, characterized in that output from the memory queue. 29. The coding system according to claim 28, wherein the bit pack apparatus has a bit packing logic for receiving code words from the rearrangement apparatus and mixing code words and interleaved words for a plurality of columns. 38. The coding system of claim 37, wherein the bit packing logic comprises a plurality of accumulators and a plurality of registers, each of the plurality of registers associated with one of the plurality of accumulators and one of the plurality of columns. 39. The apparatus of claim 38, wherein the encoding system comprises a shifter coupled to a plurality of accumulators for shifting codewords in response to at least one signal from a plurality of accumulators, wherein the codewords include at least two codewords within each interleaved word. A coding system, characterized in that shifted to interpolate contents in one of a plurality of registers based on an accumulator value for a pack region. 38. The encoding system according to claim 37, wherein said encoding system comprises a rearrangement memory for storing interleaved words in the order indicated by the decoder. 41. The system of claim 40, wherein the encoding system comprises a plurality of pointers corresponding to a plurality of interleaved data columns, each of the plurality of pointers indicating a location in the rearrangement memory for the next interleaved for each of the plurality of columns. Encoding system, characterized in that. 29. The system of claim 28, wherein the encoding system comprises a plurality of execution coefficient rearranging apparatuses, each of the plurality of execution coefficient rearranging apparatuses associated with one of the encoded data strings, the interleaved for each encoded data string. And a decoder for selecting an interleaved word from the plurality of bit pack devices as a coded output. 29. The apparatus of claim 28, wherein the encoding system is associated with one of the encoded data strings and generates a plurality of codewords and a timestamp associated with each of the plurality of codewords, and each encoded data string. And a plurality of bit pack devices for generating interleaved words, and logic for selecting each interleaved word based on timestamps of code words in each interleaved word. 44. The encoding system of claim 43, wherein the logic selects an interleaved word including a codeword having the oldest timestamp. 29. The apparatus of claim 28, wherein the bit pack apparatus is configured to receive a codeword from one of a plurality of columns, and a logic for selecting an interleaved word output from each of the plurality of bit packers based on a next column. An encoding system characterized by having. 29. The coding system according to claim 28, wherein said rearranging device comprises a limit memory. A coding system for processing data, comprising: an index generator for generating indexes based on the data, and a state table coupled to provide a probability estimate based on the indexes, the state table being the first multiple states and the second. Including multiple states, each of which corresponds to a sign, plus a transition of another code variant that conforms to the first majority state to a transition between other codes that conform to the second majority state when transitioning from the second majority state. Coating systems characterized by faster transitions between states. 48. A coating system according to claim 47, wherein said first multistate is used only for a set number of indices. 48. A coating system according to claim 47, wherein the first majority state is used for only a set number of indexes initially indexed in the state table. 48. A coating system according to claim 47 wherein each of said first plurality of states is associated with an R2 code. 49. The method of claim 48, wherein the first plurality of states includes at least one transition to a second plurality of states, such that the state table transitions from the first plurality of states to the second plurality of state tables after a set number of indexes. Coating system. 48. The coating system of claim 47, wherein each of said first plurality of states is associated with different symbols. 48. A coating system according to claim 47, wherein said state table transitions from one of the first plurality of states to one of a second plurality of states in response to a minimum possible signal. 48. A coating system according to claim 47, wherein the state machine increases the state in response to an optimal possible symbol. A coating system for processing data, the coating system comprising: an index generator for generating indices based on the coating system; and a state table coupled to provide a probability estimate based on the index; Where each state corresponds to a sign and all the signs in the state table are repeated a set number of times and transitions between states in the state table occur on an accelerating basis, resulting in a first rate of transition between states during the first period. Coating system characterized by a difference from the second rate of transition during the second period. 56. The coating system of claim 55, wherein the coding system has a PEM state wherein the update to the state table changes as the acceleration increases or decreases. 59. A coating system according to claim 56, wherein adaptive acceleration does not occur when the acceleration type is configured with a set number. 59. The coating system according to claim 56, wherein the acceleration type is updated based on the number of executable codewords. 59. The coating system of claim 58, wherein the executable codeword consists of an executable codeword in context. 59. The coating system of claim 58, wherein the executable codeword consists of an executable codeword in a probability CLASS. The coating system according to claim 56, wherein the acceleration type is updated based on the number of codewords changed. An entropy decoder for decoding data streams of a plurality of codewords, wherein the entropy decoder is connected to a plurality of bit string generators for receiving the data strings and to a plurality of bit string generators to provide a probability estimate to the plurality of bit string generators. A plurality of bit string generators generate a decoded result for each codeword in the data string in response to a probability estimate using the Rn (k) code for a multi-value of n; Entropy, which includes a first majority state and a second majority state, wherein transitions between different codes in the first majority state occur faster than transitions between signs when transitioning in the second majority state Decoder. 63. The entropy decoder of claim 62, wherein each of the first plurality of states comprises an R2 (k) code. 63. The entropy decoder of claim 62, wherein the first majority state is used only during initialization. An entropy decoder for decoding data streams of a plurality of codewords, the entropy decoder having a plurality of bit string generators for receiving data streams, and a state table coupled to provide an index based probability estimate. The table contains a number of states, each of which is coded and matched, all states of the state table are repeated on a set number of times, and transitions between states of the state table occur on an accelerating basis, and thus during the first time period. An entropy decoder wherein the first rate of transition between states differs from the second rate of transition during the second period. 63. The entropy decoder of claim 62, wherein all of the signs in the state table are repeated a fixed number of times. 67. The entropy decoder according to claim 66, wherein the update to the state table constitutes a changing PEM state by the acceleration type. 67. The entropy decoder of claim 67, wherein no adaptive acceleration occurs when the acceleration type is configured with a set number. The entropy coder according to claim 69, wherein the acceleration type is updated based on the number of executable codewords. 68. The entropy decoder according to claim 67, wherein the acceleration type is updated based on the number of codewords changed by the acceleration type. A decoder for decoding a plurality of interleaves, wherein the decoder receives a data string and outputs coded data that is properly aligned, and a shifter connected to the shifter to receive coded data such as codewords that are properly aligned. A run length decoder for determining the code length, and a run length decoder for determining a code for the run length decoder, and the run length protector generates an indication of whether the LPS is generated in response to the run length and each codeword. A variable length shifting device having a device, wherein the shifter shifts a codeword from a data string, and connected to receive a codeword from a column in response to the shifting device in which aligned codeword data is output as a serial codeword. A decoder comprising a plurality of registers. 72. The decoder of claim 71 wherein the register portion is coupled to receive data from another plurality of registers or data strings. 76. The decoder of claim 71, wherein the variable shifting device includes a cylindrical shifter for shifting data from a row to a plurality of registers. 72. The apparatus of claim 71, wherein the shifter comprises a FIFO having a plurality of registers, each of the registers receiving data as input from interleaved encoding data, wherein at least one of the plurality of registers is from another another plurality of registers. And a decoder connected to receive the codeword. 72. The apparatus of claim 71, wherein the shifter comprises: a first plurality of registers, each register coupled with a distinct one of a plurality of columns, and coupled to receive code data; and a first code such as an output code to an input code from one of the plurality of columns at the same time. A multiplexer connected to receive code data from each of the plurality of registers, a cylindrical shifter connected to an output of the multiplexer to shift coded data from the interruption outputting assigned coded data, and a bit shifting codeword A FIFO having logic coupled to a cylindrical shifter to represent a number, and a FIFO having a plurality of registers coupled to receive codewords from the multiplexer 1605, wherein the FIFO includes a plurality of registers, each of the plurality of registers Receive data as input from this interleaved encoding data. Number and the decoder characterized by at least one of the registers connected to the again received from the other register number of code words. A decryption system for decrypting data, comprising: a FIFO structure connected to receive said decryption system data, a contextual module for producing a context, and a contextual module for storing state information, each provided by a contextless module A plurality of decoders coupled to receive encoded data from the memory providing status information in response to a context, and from the FIFO structure and a memory for decoding codes and codewords provided from the FIFO structure, wherein the plurality of decoders have an execution coefficient. Decoding system, characterized in that provided to be generated for a plurality of codes. 77. The decoding system of claim 76, wherein the FIFO structure provides encoded data to a plurality of decoders independently of context and probability CLASS. 77. The decoding system according to claim 76, wherein said decoder comprises an execution coefficient memory for storing an execution coefficient, and said execution coefficient memory can be calculated based on probability CLASS. 77. The decoding system of claim 76, wherein said FIFO structure provides data for two decoders. 77. The decoding system of claim 76, wherein said FIFO structure has a plurality of outputs, one for each decoder. 81. The decoding system of claim 80, wherein the FIFO structure includes a multiplexer pair and a control logic for selecting the multiplexer pair to ensure that a codeword is provided to each decoder. 84. The decoding system of claim 81, wherein the multiplexer pair is selected by control logic based on a request received from one of a plurality of decoders. An encoding system for encoding input data, the encoding apparatus being connected to receive input data to generate data encoded in the form of a plurality of columns of the encoding system and wherein the encoded data is assigned to one of a plurality of columns based on a set of features. And less important coded data connected to an encoding device for storing a plurality of coded data sequences includes a fixed size memory that is discarded if the fixed size memory is oversaturated. 84. The coding system according to claim 83, wherein said memory comprises a plurality of storage areas, and the encoded data stored in each of said plurality of storage areas is a code of a particularly important class. 85. The coding system of claim 84, wherein said significant class of encoded data is stored in at least one storage area of memory that stores another significant level of encoded data. 86. The coding system of claim 85, wherein said significant class of encoded data is overwritten on top of another significant class of encoded data in at least one storage area of memory. A method of initializing a plurality of contexts in a system while coding data, the method comprising the steps of initializing a plurality of contexts in which each context is accessed based on a count value, and each context representing its PEM state. Accessing the storage indication to determine whether the stored storage location is valid for the current operation by comparing the current context number with the count value, so if the count value indicates an already initialized location, the data is valid. Using the initial PEM state for the context and ignoring the current PEM state for the context when the data in the accessed memory location is invalid, and the PEM state currently assigned for the context if the data is valid. Acquiring a PEM state of the current context provided by using a plurality of contexts in the system, characterized in that How to initialize. 88. The method of claim 87, wherein said method has a new PEM state if the PEM state changes. A decoder for decoding input data, the decoder being coupled to a context model for providing a context box, a memory associated with the context model to provide a probability state based on the context box, and a probability class based on the probability state. And a plurality of bit generators coupled to the logic to generate a possible signal based on a probability state, and a plurality of bit generators connected to the decoder and connected to receive encoded data, each of the plurality of bit generators being at least A decoder, devoted to one separate (clear) code, wherein said decoder is capable of one of a plurality of bit generators based on probability CLASS, so that one of said plurality of bit generators encodes coded data. . 90. The method of claim 89, wherein at least one of the plurality of bit generators decodes data using an R- code, and at least one of the plurality of bit generators decodes data using a non-R-code. Decoder. 90. The decoder of claim 89, wherein the bit generator for short execution length operates as an R- code decoder. 90. The bit generator of claim 89, wherein the bit generator for the long execution length comprises a short execution device and a long execution device, wherein the short execution device drives the symbols of the first set length, and the long execution device is left with other remaining bits. If the output is a decoder, characterized in that for driving the determined bit. In the input data decoding method, the method includes providing a context box, accessing a memory using a context box to obtain a probability state, and generating a probability class based on the probability state. Each of the plurality of bit generators, which enables one of the bit generators, is devoted to at least one distinct code, so that only the one distinct code above is used for decoding, and one of the plurality of bit string generators is encoded. And decrypting the data. An encoding system for encoding input data, comprising: a memory model coupled to a context module to provide a context model providing the encoding system context box and a probability state based on a context box, and a memory coupled to generate a probability CLASS based on a probability state; A plurality of bit generators connected to an encoder and a decoder connected to logic to generate a possible signal based on logic and probability CLASS, and connected to receive input data, each of the plurality of bit generators being dedicated as a separate code, And wherein the code can use one of a plurality of bit generators based on a probability CLASS, so that one of the plurality of bit string generators encodes input data. 95. The method of claim 94, wherein at least one of the plurality of bit generators encodes data using an R- code, and at least one of the plurality of bit generators encodes data using a non-R-code. Coding system. 95. The encoding system of claim 94, wherein the bit generator for the short execution length operates as an R- code encoder. 95. The apparatus of claim 94, wherein the bit generators for the long execution length comprise a short execution device and a long execution device, the short execution device drives a sign of a first set length, and the long execution device drives a remaining bit, And if so, determine to output the remaining bits. In the input data encoding method, the method includes providing a context box, accessing a memory using a context box to obtain a probability state, generating a probability class based on the probability state, and a plurality of bits. Enabling one of the generators and each of the plurality of bit generators is dedicated to at least one distinct code, so that only the one distinct code described above is used for encoding and one of the plurality of bit string generators Encoding the input data. A method of decoding coded data comprising a plurality of codewords, wherein the method loads a coefficient value into a counter associated with each execution counter, the size of the codeword memory used during encoding when a new execution is started. In terms of, the coefficient value step loaded when a new codeword for each execution counter is called and the step of decreasing the coefficient value each time any codeword is called and associated with the new codeword when the count value is reduced to zero. CLEAR a bit generator state. 100. The method of claim 99, wherein each execution counter corresponds to a PEM state. 100. The method of claim 99, wherein each execution counter corresponds to a context box. A method of decoding coded data comprising a plurality of codewords, the method comprising: incrementing a coefficient value each time a codeword is requested, wherein the coefficient value includes a current-number indication and stored at the beginning of the first codeword. Storing the count value as the count display and comparing the stored count display with the current count display added to the size of the encoder memory, wherein the bit generator state for the first code word is cleared and the second code word is the current count display. Encoding when the size of the memory is larger than the added stored count indication. 107. The method of claim 102, wherein the stored number of times indication comprises a time STAMP. 103. The method of claim 102, comprising reusing a stored count indication for a codeword following said method. A method for decoding coded data having a plurality of codewords, the method comprising invalidating and storing an index that matches a codeword as the index is stored in a queue and the index is stored when a codeword is requested. In the step of indicating the entry of the index in the queue, storing the codeword in the entry, and marking it as valid if the codeword is complete, and decoding and outputting the codeword if the queue entry is valid, outputting data from the decoded queue. Outputting data from the queue entry and the queue entry, and if the queue entry is marked invalid when outputting the data from the queue entry, marking the data as invalid on the decoder; Cleared by the decoder in response to receiving. In the decoder for decoding the coded data, the decoder includes a context modeling device for providing a context in which the context modeling device is composed of a plurality of integrated circuits, and the memory for storing state information in connection with the context model. Provide status information in response to each context provided by the plurality of decoders coupled to and coupled to the memory to decode the codeword using the status information from the memory. The plurality of decoders decode the codewords using a plurality of R codes. And wherein the plurality of R codes comprises a plurality of decoders, including at least one non-maximum length execution of the traceable symbols followed by the least possible symbols. 107. The decoder of claim 106, wherein the non-maximum length execution coefficient has the same protectable PREFIX. A system for decoding a code string having a plurality of codewords, the system comprising a context modeling device for providing a context in which the context modeling device includes a plurality of integrated circuits, and the memory of the context modeling device. In providing status information in response to each provided context, a memory is connected to the context model to store the status information, and a plurality of decoders are connected to the memory to decode codewords using the status information from the memory. Decryption system characterized in that. 109. The apparatus of claim 108, wherein the context modeling device includes at least one context model for providing a context from one of a plurality of integrated circuits and at least one context model for providing a context from a second of the plurality of integrated circuits. Decryption system. 109. The decoding system of claim 109, wherein in at least one of the plurality of integrated circuits, the at least one context model comprises a zero order context model. 109. The system of claim 108 wherein contexts from a plurality of integrated circuits are provided directly to the memory. 109. The decoding system of claim 108, wherein the first portion of the first context is provided by one integrated circuit and the second portion of the first context is provided by a second integrated circuit. 18. The decoding system according to claim 17, wherein the bit generator state of the bit generator is updated, and the bit generator is first used in an updated state written in a memory. 116. The decoding system of claim 113, wherein said bit generator is reused during a modification stage of a read-modify-write-cycle. 18. The coding system of claim 17, wherein the bit generator generates a non-circuit length execution count when reused prior to writing an updated state to memory. 18. The method of claim 17, wherein the bit generator encodes data using an R- code defined such that each execution length is followed by at least one unenriched bit, so that the same execution length is never decoded into columns. Coding system. A system for decoding a code string having a plurality of codewords, the context modeling apparatus in which the system provides a context, and a context associated with the context model to store state information, each memory provided by the context model. Provide status information in response to the memory, the at least one of the plurality of decoders having a delay-tolerant decoder coupled to the memory to decode the codeword using the status information from the memory, and a plurality of decoders. Decryption system characterized in that. 116. The decoding system of claim 115, wherein at least one of the plurality of decoders shifts the variable length based on the decoded data possible after a delay. 118. The decoding system of claim 117, wherein variable length data is received as an input of each of said plurality of decoders. 119. The decoding system of claim 119, wherein the plurality of decoders decode variable length input data in parallel. 172. The decoding system of claim 171, wherein outputs of the plurality of decoders are divided into fixed length interleaved words. ※ Note: It is to be disclosed based on the initial application.