JP2009016993A - Composition processor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a composition processor capable of rapidly carrying out composition processing, while saving the storage capacity for storing a composite-function table and a communications device. <P>SOLUTION: The communications device conducts composition processing for compositing a plurality of processes prescribed so as to be successively carried out, and has an internal storage device 24 and a communication control section 21. The internal storage device 24 is obtained, by combining a plurality of function tables indicating corresponding relations among input data and output data for processing, and previously stores the composite function tables indicating relations among the input data and the output data for composition processing. The communication control section 21 conducts control so as to successively store the composite function tables, starting from the descending order of priority. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a synthesis processing apparatus that performs a synthesis process in which a plurality of processes defined to be sequentially executed are combined, and a communication apparatus to which the synthesis processing apparatus is applied.

  In a conventional communication device, an algorithm for performing transmission data encoding processing and reception data decoding processing is appropriately selected from a plurality of algorithms to reduce the device configuration and reduce power consumption. (See Patent Document 1 below).

  Furthermore, in order to realize small-scale and low power consumption, there is a method of converting a part of encoding processing and decoding processing into a synthesis function and processing at high speed. A case where this method of combining functions is applied to a radio base station of a W-CDMA (Wide-band Code Division Multiple Access) mobile radio system will be described below (see Non-Patent Document 1 below). The radio base station has a transport channel as an interface for data communication with a host device and a radio channel as an interface for data communication with a mobile station. The radio base station encodes a transport channel data group received from one or more transport channels and transmits the encoded data to the mobile station via the radio channel. The transport channel data is received at an interval called TTI (Transmission Time Interval) notified in advance from the host device. TF (Transport Format), which is the format of transport channel data, changes every time it is received, and is determined by an identifier TFI (Transport Format Indicator) added to the data header. A combination of TFs is called TFC (Transport Format Combination), and a set of TFCs that can be used for communication is called TFCS (Transport Format Combination Set). The TFCS is notified in advance from the host device.

  For example, the radio base station apparatus can process a part of the encoding at a high speed using the synthesis function table. However, since the content of the composite function table changes for each TFC, the composite function table is required for TFCS. Therefore, it is necessary to prepare a composite function table for TFCS for each communication call type, which causes a problem that the capacity of the internal storage device for storing the composite function table becomes enormous.

JP2005-109909 (paragraph 0016) 3GPP (3rd Generation Partnership Project) standard TS25.212

  Conventional communication devices use a synthesis function table as part of the process of encoding transmission data in order to reduce the device configuration to a small scale and consume less power, but can support all supported communication call types. As described above, since a composite function table for all channel types × TFCS is held in advance, a large amount of internal storage capacity for the composite function table is required. Therefore, a method of generating a composite function table for TFCS only when necessary to save internal storage capacity (during channel setting and channel reconfiguration) can be considered. In the meantime, the service cannot be started. Also, if the service is started before the generation of all synthesis functions is completed, if data for which no synthesis function is generated is received, encoding and decoding cannot be performed, communication is interrupted, and communication quality deteriorates. Resulting in.

  In view of the above-described problems of the prior art, the present invention has applied a synthesis processing apparatus that can quickly execute a synthesis process while saving storage capacity for storing a synthesis function table, and the synthesis processing apparatus. It is an object of the present invention to provide a communication apparatus that can maintain communication quality.

The present invention relates to a synthesis processing apparatus that performs a synthesis process in which a plurality of processes defined to be sequentially executed are synthesized.
A composite function storage for storing a composite function table indicating the relationship between the input data and the output data of the composite process, obtained by combining a plurality of function tables indicating the correspondence relationship between the input data and the output data of the process And
And a control unit that performs control so as to store in order from a synthesis function table having a high priority.

  The synthesis processing apparatus of the present invention is applied to a communication apparatus that communicates with the outside, and the process is a process of encoding transmission data or decoding reception data.

  According to the synthesis processing apparatus of the present invention, the synthesis process can be quickly executed while saving the storage capacity for storing the synthesis function table by storing the synthesis function tables in order from the highest priority. Moreover, according to the communication apparatus to which the composition processing apparatus of the present invention is applied, it is possible to maintain communication quality.

Embodiment 1 FIG.
FIG. 1 is a flowchart showing a downlink encoding process flow. Here, a downlink encoding process compliant with the 3GPP standard will be described.

  First, in step a1, CRC bits for performing CRC (Cyclic Redundancy Check) are added to the transport block (TrBK). Next, in step a2, the transport blocks are combined and divided into encoded blocks. Next, in step a3, channel coding is performed. Next, in step a4, rate matching processing for complementing or thinning data is performed. Next, in step a5, a first DTX insertion process for inserting a DTX (Discontinuous Transmission) bit is performed. Next, in step a6, a first interleaving process for changing the data order is performed. Next, in step a7, a process of dividing each radio frame is performed.

  Next, in step a8, a process of multiplexing for each transport channel (TrCH) is performed. Next, in step a9, a second DTX insertion process is performed. Next, in step a10, processing for dividing each physical channel is performed. Next, in step a11, a second interleaving process is performed. Next, in step a12, a process of mapping data for each physical channel (PhCH) is performed.

  Among the downlink encoding processes as described above, a processing method using a synthesis function is applied to a synthesis process obtained by synthesizing the processes of steps a4 to a12.

  The composite function table is obtained by combining a plurality of function tables indicating the correspondence between the input data and output data of each process. Here, the input data of the composite function table is b1,..., Bn, and the output data is c1,. At this time, a part of the output data can be expressed as rearrangement of input data (ci = bj) or a fixed value (ci = x). Therefore, yi and zi are defined as ci = bzi if yi = 0 and ci = zi if yi = 1. At this time, by storing y1, ..., ym and z1, ..., zm as arrays, conversion from b1, ..., bn to c1, ..., cm can be executed at high speed. Such an array is called a composite function table. The composite function table can be generated by giving increment data bi = i as input data to the composite function, simulating the actual processing of the composite function, and using the output data obtained as a result.

  Also, the priority of the synthesis function table is defined as follows. It is assumed that TFCS notified in advance from the host device is J, the synthesis function corresponding to TFCjεJ is Zj, the priority for Zj is Pj, and the higher the priority, the higher the priority.

  FIG. 2 is a diagram showing a transmission side configuration of the communication apparatus according to Embodiment 1 of the present invention. The communication device includes a communication control unit 21, a generation waiting combination function queue 22, a combination function generation unit 23, an internal storage device 24, and an encoding processing unit 25.

  The communication control unit 21 manages and controls parameters, calculates the priority of the synthesis function for each TFC of the target channel at the time of channel setting or channel reconfiguration, and assigns the synthesis function to the generation waiting synthesis function queue 22. to add. The generation-waiting synthesis function queue 22 is a memory for temporarily storing a synthesis function waiting for generation. The added synthesis functions are stored in the order of priority, and when they are extracted, the highest priority Pj is synthesized. This is a mechanism that can acquire the function Zj. The generation waiting synthesis function queue 22 is initialized to an empty state when the communication apparatus is activated. The synthesis function generation unit 23 extracts the synthesis function from the generation waiting synthesis function queue 22, generates a synthesis function table, and stores the synthesis function table in the internal storage device 24. The internal storage device 24 is a storage device that stores the generated synthesis function table. The encoding processing unit 25 is a processing unit that receives transport channel data as input, performs encoding processing, and outputs transmission data. A synthesis function table is provided as part of the encoding processing (steps a4 to a12). Use.

  FIG. 3 is a flowchart illustrating a processing flow of the synthesis function generation unit. The synthesis function generator takes an infinite loop structure. After the processing is started in step b0, it is determined in the next step b1 whether the generation waiting synthesis function queue 22 is empty. If it is empty, the process returns to step b1, and the process of step b1 is repeated until the synthesis function is added to the generation waiting synthesis function queue 22. If there is a synthesis function in the generation waiting synthesis function queue 22, the synthesis function is extracted in the next step b2. Subsequently, in the next step b3, a synthesis function table is generated. When the generation of the synthesis function table is completed, the process from step b1 to b3 is repeated until the process returns to step b1 and the generation waiting synthesis function queue 22 becomes empty.

Next, four methods for calculating the priority order Pj will be described.
(Priority calculation method 1)
Priority order calculation method 1 is a method for maintaining channel connection. If communication of transport channels including DCCH (Dedicated Control Channel) that is a control logical channel is unstable, a channel stretched between the radio base station and the mobile station may be disconnected. In consideration of such circumstances, the calculation method of the priority order Pj is determined as follows. The set of transport channels is I, and the TFI of transport channel i of TFCj is Ti, j. Next, a weight ωctli is determined for each transport channel i. The weight ωctli ′ of the transport channel i ′ including the DCCH is set to be relatively large with respect to the weights of the other transport channels. From the parameter group defined above, control channel priority Pctlj

と定義する。C1はオフセット値であり、他の優先順位の算出方法と整合性を取るためのパラメータである。制御チャネル用優先順位Pctlｊは必ずしも前記のように定義する必要はなく、ＤＣＣＨの通信が途切れないように、ＤＣＣＨを含む合成関数の生成を優先して行えるように優先順位を設定できれば、どのような方法でもよい。
（優先順位の算出方法２）
優先順位の算出方法２は、通信中の無線チャネルに対してチャネル再構成が行われる場合に通信中の送信データを継続できるようにする方法である。チャネル再構成によってトランスポートチャネルi'が追加される場合について説明する。チャネル再構成前のトランスポートチャネルの集合をＩ、再構成後のトランスポートチャネルの集合をＩ'（集合Ｉにi'が加わったもの）とする。チャネル再構成前のトランスポートチャネルiで受信していたトランスポートチャネルデータのＴＦＩをTiとし、追加されたトランスポートチャネルi'のＴＦＩをＴｉ'=0とする。チャネル再構成後のＴＦＣjのトランスポートチャネルiのＴＦＩをＴｉ,ｊとする。通信継続用の優先順位Ｐconｊを

It is defined as C1 is an offset value, which is a parameter for ensuring consistency with other priority calculation methods. The control channel priority Pctlj does not necessarily have to be defined as described above. If the priority can be set so that the generation of the synthesis function including the DCCH can be performed with priority, the DCCH communication is not interrupted. It may be a method.
(Priority calculation method 2)
The priority calculation method 2 is a method for allowing transmission data being communicated to be continued when channel reconfiguration is performed for the radio channel being communicated. A case where the transport channel i ′ is added by channel reconfiguration will be described. A set of transport channels before channel reconfiguration is I, and a set of transport channels after reconfiguration is I ′ (i ′ added to set I). It is assumed that the TFI of the transport channel data received on the transport channel i before channel reconfiguration is Ti, and the TFI of the added transport channel i ′ is Ti ′ = 0. Let TIF of the transport channel i of TFCj after channel reconfiguration be Ti, j. Priority Pconj for continuing communication

と定義する。C2はオフセット値であり、他の優先順位の算出方法と整合性を取るためのパラメータである。また、関数DはD(x,y)=|x-y|やD(x)=(x-y)2 のようなxとyの距離を表す関数であればよく、これに限るものではない。また、通信継続用の優先順位Ｐconｊは再構成前に通信していたチャネルを優先するように設定すればよい。

It is defined as C2 is an offset value and is a parameter for ensuring consistency with other priority calculation methods. Further, the function D may be a function representing the distance between x and y such as D (x, y) = | xy | and D (x) = (xy) 2, and is not limited to this. Further, the priority Pconj for continuing communication may be set so that the channel communicated before reconfiguration is prioritized.

  Even when the transport channel i ′ is deleted by channel reconfiguration, the communication continuation priority Pconj is set in the same manner as described above.

と定義する。チャネル再構成前にデータ導通していたトランスポートチャネルは、チャネル再構成をはさんで引き続きデータが導通し続ける。一方で、チャネル再構成によって追加されたトランスポートチャネルはすぐにデータ導通が開始することは少ない。したがって、チャネル再構成前にデータ送信していたトランスポートチャネルを優先して合成関数テーブルの生成を行うようになるため、通信を継続したままチャネル再構成ができる。
（優先順位の算出方法３）
優先順位の算出方法３は、通信中の無線チャネルに対してチャネル再構成が行われる場合にリアルタイム性の必要なトランスポートチャネルを優先するものである。チャネル再構成後のトランスポートチャネルの集合をＩ'、ＴＦＣｊのトランスポートチャネルiのＴＦＩをTi,jとする。次に各トランスポートチャネルiに対して重みωrliを定める。リアルタイム性の必要なトランスポートチャネルi'の重みωrli'を、他のトランスポートチャネルの重みに対して相対的に大きく設定する。リアルタイム用優先順位Prlｊを

It is defined as A transport channel that has been conducting data before channel reconfiguration continues to conduct data across the channel reconfiguration. On the other hand, the transport channel added by channel reconfiguration hardly starts data conduction immediately. Therefore, since the synthesis function table is generated with priority given to the transport channel that has transmitted data before channel reconfiguration, channel reconfiguration can be performed while communication is continued.
(Priority calculation method 3)
The priority calculation method 3 gives priority to a transport channel that requires real-time characteristics when channel reconfiguration is performed on a wireless channel in communication. Assume that the set of transport channels after channel reconfiguration is I ′, and the TFI of transport channel i of TFCj is Ti, j. Next, a weight ωrli is determined for each transport channel i. The weight ωrli ′ of the transport channel i ′ requiring real-time property is set relatively large with respect to the weights of other transport channels. Real-time priority Prlj

と定義する。C3はオフセット値であり、他の優先順位の算出方法と整合性を取るためのパラメータである。リアルタイム用優先順位Prlｊは、必ずしも前記のように定義する必要はなく、リアルタイム性を求められるトランスポートチャネルのデータが途切れないように、合成関数の生成を優先して行えるように優先順位を設定できればよく、これに限るものではない。例えば、音声データ用のトランスポートチャネルをリアルタイム性の必要なトランスポートチャネルとし、本算出方法を適用することにより、音声が途切れることなくチャネル再構成を行うことができる。
（優先順位の算出方法４）
優先順位の算出方法４は、通信中の無線チャネルに対してチャネル再構成が行われる場合、再送可能なトランスポートチャネルを含む合成関数の優先順位を下げることによって、総合的な通信品質を向上するものである。チャネル再構成後のトランスポートチャネルの集合をI'、ＴＦＣｊのトランスポートチャネルｉのＴＦＩをＴｉ,ｊとする。次に各トランスポートチャネルiに対して重みωretiを定める。データの再送可能なトランスポートチャネルi'の重みωreti'を、他のトランスポートチャネルの重みに対して相対的に小さく設定する。再送可能用低優先順位Pretｊを

It is defined as C3 is an offset value, and is a parameter for ensuring consistency with other priority calculation methods. The real-time priority Prlj does not necessarily have to be defined as described above, and if the priority can be set so that the generation of the synthesis function can be performed with priority so that the transport channel data for which real-time property is required is not interrupted. Well, not limited to this. For example, by using the transport channel for audio data as a transport channel that requires real-time property and applying this calculation method, it is possible to perform channel reconfiguration without interrupting audio.
(Priority calculation method 4)
The priority calculation method 4 improves the overall communication quality by lowering the priority of the combining function including the retransmittable transport channel when channel reconfiguration is performed on the radio channel in communication. Is. Assume that the set of transport channels after channel reconfiguration is I ′, and the TFI of transport channel i of TFCj is Ti, j. Next, a weight ωreti is determined for each transport channel i. The weight ωreti ′ of the transport channel i ′ that can retransmit data is set relatively small with respect to the weights of other transport channels. Low priority Pretj for resend possible

と定義する。C4はオフセット値であり、他の優先順位付け方法と整合性を取るためのパラメータである。再送可能用低優先順位Pretｊは、必ずしも前記のように定義する必要はなく、データの再送可能なトランスポートチャネルの合成関数の生成の優先順位を低く設定できればよく、特に定めない。例えば、再送可能なパケット用のトランスポートチャネルに対して、本実施例を適用することにより、総合的な通信品質を向上することができる。パケット用のトランスポートチャネルを含む合成関数の生成が後回しにされるため、パケット用のトランスポートチャネルの通信品質は劣化するが、再送可能であるため、通信品質の劣化は少なく抑えられる。一方、その他のトランスポートチャネルの合成関数の生成を優先できるようになるため、全トランスポートチャネルを総合した通信品質は向上させることができる。

It is defined as C4 is an offset value and is a parameter for consistency with other prioritization methods. The retransmittable low priority Pretj does not necessarily need to be defined as described above, and is not particularly limited as long as the priority of generating a data channel retransmittable composite function can be set low. For example, the overall communication quality can be improved by applying this embodiment to a transport channel for retransmittable packets. Since the generation of the synthesis function including the packet transport channel is postponed, the communication quality of the packet transport channel is deteriorated, but since the retransmission is possible, the deterioration of the communication quality is suppressed to a small extent. On the other hand, since the generation of the synthesis function of other transport channels can be prioritized, the communication quality of all the transport channels can be improved.

  As described above, by storing in order from the synthesis function table with the highest priority, the synthesis process can be executed quickly while saving the storage capacity for storing the synthesis function table. In addition, communication quality can be maintained.

Embodiment 2. FIG.
FIG. 4 is a diagram showing a transmission side configuration of the communication apparatus according to Embodiment 2 of the present invention. In the second embodiment, a priority control unit 46 is added to the configuration of the first embodiment. The priority control unit 46 applies the four priority calculation methods described in the first embodiment in combination, and appropriately selects each priority calculation method according to the channel status. Specifically, the priority Pj
Pj = Ectl × Pctlj + Econ × Pconj + Erl × Prlj + Eret × Pretj (5)
Calculate as follows. Ectl, Econ, Erl, and Eret are priority control variables that take a value of 0 or 1 depending on the situation. The priority order control unit 46 is a control unit that appropriately sets priority order control variables according to the situation.

  When the communication control unit 41 newly sets a channel or reconfigures a channel (addition of a transport channel or deletion of a transport channel), the communication control unit 41 calculates the priority for calculating the priority of the synthesis function table. The control unit 46 is inquired about the priority control variable. Upon receiving the inquiry, the priority control unit 46 determines the status of the target channel and notifies the communication control unit 41 of the priority control variable.

  Subsequently, processing in the priority control unit 46 will be described. First, in order to always apply the priority Pctlj for the control channel that does not depend on the situation and the priority Pretj for retransmission, both Ectl and Eret are fixed to 1. Since the priority Pconj for continuing communication is applied only at the time of channel reconfiguration, Econ = 1 is set in the case of channel reconfiguration, and Econ = 0 is set otherwise. For the priority Prlj for real-time, a transport channel for voice data and a transport channel for videophone are selected as channels requiring real-time characteristics, and real-time characteristics are required before and after channel reconfiguration. Set Erl = 1 when the channel continues communication, otherwise set Erl = 0. The communication control unit 41 is notified of the priority control variables Ectl, Econ, Erl, and Eret obtained as described above.

  As described above, it is possible to further improve the communication quality by assigning the priorities finely according to the situation.

Embodiment 3 FIG.
FIG. 5 is a diagram showing a transmission side configuration of a communication apparatus according to Embodiment 3 of the present invention. In the first embodiment, the synthesis function table is actually generated in the synthesis function generation unit 23. However, in the third embodiment, the synthesis function table generated in advance is stored in the external storage device 57. Download when needed. In the third embodiment, an external storage device 57 is added to the configuration of the first embodiment. A composite function table for TFCS is stored in advance in the external storage device 57 for each communication call type, and the composite function generation unit 53 downloads the composite function table from the external storage device 57 and stores it in the internal storage device 54. .

  With such a configuration, the internal storage capacity can be saved, and the synthesis process can be executed quickly.

Embodiment 4 FIG.
FIG. 6 is a flowchart showing an uplink decoding process flow. Here, an uplink decoding process based on the 3GPP standard will be described. Similar to the first embodiment, the same technique can be applied to the decoding process of the communication device on the receiving side.

  First, in step c1, data is mapped for each physical channel (PhCH). Next, in step c2, a second deinterleave process that is the reverse of the second interleave process performed on the transmission side is performed. Next, in step c3, processing for combining physical channels is performed. Next, in step c4, a process of separating each transport channel (TrCH) is performed.

  Next, in step c5, a rate dematching process is performed in which the data supplemented or thinned out on the transmission side is thinned out or complemented. Next, in step c6, processing for combining wireless frames is performed. Next, in step c7, a first interleaving process that is the reverse of the first interleaving process performed on the transmission side is performed. Next, in step c8, processing for removing the padded bits on the transmission side is performed. Next, in step c9, channel decoding processing is performed. Next, in step c10, a process of combining the encoded blocks and dividing the blocks into transport blocks (TrBK) is performed. Next, in step c11, a CRC check is executed.

  Among the uplink decoding processes as described above, a processing method using a synthesis function is applied to the synthesis process obtained by synthesizing the processes of steps c2 to c8.

  FIG. 7 is a diagram showing a reception-side configuration of a communication apparatus according to Embodiment 4 of the present invention. The communication apparatus includes a communication control unit 71, a generation waiting synthesis function queue 72, a synthesis function generation unit 73, an internal storage device 74, and a decoding processing unit 75.

  The communication control unit 71 manages and controls the parameters, calculates the priority of the synthesis function for each TFC of the target channel at the time of channel setting or channel reconfiguration, and adds the synthesis function to the generation waiting synthesis function queue 72. to add. The generation-waiting synthesis function queue 72 is a memory for temporarily storing a synthesis function waiting for generation. The added synthesis functions are stored in the order of priority, and when they are taken out, the highest priority Pj is synthesized. This is a mechanism that can acquire the function Zj. The generation waiting synthesis function queue 72 is initialized to an empty state when the communication apparatus is activated. The synthesis function generation unit 73 extracts the synthesis function from the generation waiting synthesis function queue 72, generates a synthesis function table, and stores the synthesis function table in the internal storage device 74. The internal storage device 74 is a storage device that stores the generated composite function table. The decoding processing unit 75 is a processing unit that receives received data as input, performs decoding processing, and outputs transport channel data. A decoding function table is added to a part of the decoding processing (steps c2 to c8). Use.

  FIG. 8 is a flowchart illustrating a processing flow of the synthesis function generation unit. The synthesis function generator takes an infinite loop structure. After starting the process in step d0, it is determined in the next step d1 whether the generation waiting synthesis function queue 72 is empty. If it is empty, the process returns to step d1, and the process of step d1 is repeated until the synthesis function is added to the generation waiting synthesis function queue 72. If there is a synthesis function in the generation waiting synthesis function queue 72, the synthesis function is extracted in the next step d2. Subsequently, in the next step d3, a synthesis function table is generated. When the generation of the synthesis function table is completed, the process from step d1 to d3 is repeated until the process returns to step d1 and the generation waiting synthesis function queue 72 becomes empty.

  Note that the calculation method of the priority order Pj is the same as that in the first embodiment, and thus description thereof is omitted.

  As described above, in the decoding process as well as the encoding process, the synthesis function table is stored in order, and the synthesis process is quickly executed while saving the storage capacity for storing the synthesis function table. can do. In addition, communication quality can be maintained.

Embodiment 5 FIG.
FIG. 9 is a diagram illustrating a reception-side configuration of a communication apparatus according to Embodiment 5 of the present invention. In the fifth embodiment, a priority control unit 96 is added to the configuration of the fourth embodiment. The priority control unit 96 applies a combination of the four priority calculation methods described in the first embodiment, and appropriately selects each priority calculation method according to the channel status. Specifically, the priority Pj
Pj = Ectl × Pctlj + Econ × Pconj + Erl × Prlj + Eret × Pretj (5)
Calculate as follows. Ectl, Econ, Erl, and Eret are priority control variables that take a value of 0 or 1 depending on the situation. The priority order control unit 96 is a control unit that appropriately sets priority order control variables according to the situation.

  When the communication control unit 71 sets a new channel or reconfigures a channel (adds a transport channel or deletes a transport channel), the communication control unit 71 calculates a priority order for calculating the priority order of the synthesis function table. The control unit 96 is inquired about the priority order control variable. Upon receiving the inquiry, the priority control unit 96 determines the status of the target channel and notifies the communication control unit 71 of the priority control variable.

  Next, processing in the priority order control unit 96 will be described. First, in order to always apply the priority Pctlj for the control channel that does not depend on the situation and the priority Pretj for retransmission, both Ectl and Eret are fixed to 1. Since the priority Pconj for continuing communication is applied only at the time of channel reconfiguration, Econ = 1 is set in the case of channel reconfiguration, and Econ = 0 is set otherwise. For the priority Prlj for real-time, a transport channel for voice data and a transport channel for videophone are selected as channels requiring real-time characteristics, and real-time characteristics are required before and after channel reconfiguration. Set Erl = 1 when the channel continues communication, otherwise set Erl = 0. The priority control variables Ectl, Econ, Erl, and Eret obtained as described above are notified to the communication control unit 71.

  As described above, it is possible to further improve the communication quality by assigning the priorities finely according to the situation.

Embodiment 6 FIG.
FIG. 10 is a diagram showing a reception-side configuration of a communication apparatus according to Embodiment 6 of the present invention. In the fourth embodiment, the synthesis function table is actually generated by the synthesis function generation unit 73. However, in the sixth embodiment, the synthesis function table generated in advance is stored in the external storage device 107. Download when needed. In the sixth embodiment, an external storage device 107 is added to the configuration of the fourth embodiment. A composite function table for TFCS is stored in advance in the external storage device 107 for each communication call type, and the composite function generation unit 73 downloads the composite function table from the external storage device 107 and stores it in the internal storage device 74. .

  With such a configuration, the internal storage capacity can be saved, and the synthesis process can be executed quickly.

  In the first to sixth embodiments, the synthesis function has been described. However, the synthesis function is not limited to the synthesis function, and prioritization is performed on encoding or decoding parameters that require other preprocessing. It is also possible to perform pre-processing from the highest priority. For example, the present invention can be applied to a PIL (prime interleaver) table used in an interleaver inside turbo encoding or decoding. The calculation method of the priority order is the same as that of the composite function. In this way, the internal memory can be used efficiently by executing the pre-processing related to the encoding or decoding parameters from the one with the highest priority.

It is a flowchart which shows the encoding process flow of a downlink. It is a figure which shows the transmission side structure of the communication apparatus which concerns on Embodiment 1 of this invention. 3 is a flowchart illustrating a processing flow of a synthesis function generation unit according to the first embodiment. It is a figure which shows the transmission side structure of the communication apparatus which concerns on Embodiment 2 of this invention. It is a figure which shows the transmission side structure of the communication apparatus which concerns on Embodiment 3 of this invention. It is a flowchart which shows the decoding process flow of an uplink. It is a figure which shows the receiving side structure of the communication apparatus which concerns on Embodiment 4 of this invention. 10 is a flowchart illustrating a processing flow of a synthesis function generation unit according to the fourth embodiment. It is a figure which shows the receiving side structure of the communication apparatus which concerns on Embodiment 5 of this invention. It is a figure which shows the receiving side structure of the communication apparatus which concerns on Embodiment 6 of this invention.

Explanation of symbols

21 Communication control unit (transmission side)
22 Synthesis waiting function queue (sending side)
23 Synthesis function generator (transmitting side)
24 Internal storage device (transmission side)
25 Encoding processing part (transmission side)
46 Priority Control Unit (Sending side)
57 External storage device (transmission side)
71 Communication control unit (receiving side)
72 Composing function queue waiting for generation (receiving side)
73 Compositing function generator (receiving side)
74 Internal storage (receiving side)
75 Decryption processing unit (receiving side)
96 Priority control unit (receiving side)
107 External storage device (receiving side)

Claims (13)

In a synthesis processing apparatus that performs a synthesis process in which a plurality of processes defined to be executed sequentially are combined,
A composite function storage for storing a composite function table indicating the relationship between the input data and the output data of the composite process, obtained by combining a plurality of function tables indicating the correspondence relationship between the input data and the output data of the process And
A synthesis processing apparatus comprising: a control unit that performs control so as to store in order from a synthesis function table having a high priority. The composition processing apparatus according to claim 1, wherein the composition processing apparatus is applied to a communication device that communicates with the outside, and the processing is processing for encoding transmission data or decoding reception data. 3. The composition processing apparatus according to claim 2, wherein the composition function table depends on a combination of parameters that can be changed during communication in the same communication call. 3. The synthesis processing apparatus according to claim 2, wherein a synthesis function table corresponding to a synthesis process obtained by synthesizing a process related to a control channel is prioritized over a synthesis function table corresponding to a synthesis process not synthesizing a process related to a control channel. 3. The composition processing apparatus according to claim 2, wherein a composition function table capable of continuing communication relating to data being communicated has priority over a composition function table capable of continuing communication relating to data being communicated. 3. The synthesis processing apparatus according to claim 2, wherein a synthesis function table that requires real-time property is given priority over a synthesis function table that does not require real-time property. 3. The combination function table corresponding to the combination process corresponding to the combination process combining the processes related to the retransmittable channel is prioritized over the combination function table corresponding to the combination process combining the processes related to the retransmittable channel. Synthetic processing device. The priority of the synthesis function table is given when a channel is newly set or when a channel is reconfigured to change a combination of parameters that can be changed during communication. The composition processing apparatus as described. The composition processing apparatus according to claim 1, further comprising: a priority control unit that performs control to give priority to the composition function table. The priority control unit performs control to give priority to the synthesis function table according to a factor in which channel reconfiguration has occurred at the time of channel reconfiguration to change a combination of parameters that can be changed during communication. The synthesis processing apparatus according to claim 9. The synthesis processing apparatus according to claim 1, further comprising a synthesis function generation unit that generates the synthesis function table. The composition processing apparatus according to claim 1, wherein the composition function table downloaded from an external storage device is stored in the composition function storage unit. The transmission data is encoded with a plurality of parameters, or the reception data is decoded with a plurality of parameters, and the parameters require preprocessing for encoding or decoding, and have priority over the parameters. The composition processing apparatus according to claim 1, wherein a ranking is assigned, and the parameters are preprocessed in descending order of priority.

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