JP4974748B2 - Base station apparatus, radio communication system, reception state notification method and program - Google Patents

Description

The present invention relates to a base station apparatus, radio communications systems, the reception status notification method and a program, in particular, a base that measures the reception state from the terminal device the received signal, communicates the assigned channel to the terminal apparatus based on the result station apparatus, radio communications systems, a receiving state notification method, and a program.

In order to improve communication efficiency (total system throughput and transmission speed) in a communication system, the modulation method, channel coding rate, error correction coding method, spreading factor, code multiplexing number, transmission power or An adaptive modulation method for determining a combination thereof (hereinafter referred to as a modulation parameter) has been studied (Non-Patent Document 1).
In a communication system employing an adaptive modulation method, received signal power, received signal power to noise power ratio (SNR), received signal power to interference power ratio (SIR), received signal Power to interference power and noise power ratio (SINR), carrier power to noise power ratio (CNR), carrier power to interference power ratio (CIR) ), Carrier power to interference plus noise power ratio (CINR), desired signal power to undesired signal power ratio (DUR), average received energy per symbol noise power density ratio (energy per symbol over noise spectral density ratio: E s / N 0), or the average received energy per bit Noise power density ratio (Energy per bit over Noise spectral density ratio: E b / N 0) propagation path state or reception state information an indication relating to the transmission speed, such as the selected modulation parameters in accordance with these channel conditions, such as It is necessary to notify the communication counterpart device.

In a multicarrier communication system using an Orthogonal Frequency Division Multiplex (hereinafter referred to as “OFDM”) method for transmitting information using a plurality of subcarriers, the modulation parameter is set to one subcarrier. Alternatively, an adaptive modulation method for determining each channel composed of several subcarriers has been studied (Non-patent Document 2). In the adaptive modulation method in the multicarrier communication system, it is necessary to notify the communication partner apparatus of reception state information for each channel.
Furthermore, in a communication system that includes a base station device and a plurality of terminal devices and uses multicarrier communication in communication (downlink) from the base station device to the terminal device, each channel device receives a downlink signal. A method of performing adaptive scheduling for assigning a channel to each terminal apparatus according to the state and further performing adaptive modulation has been studied (Non-Patent Document 3).

In the system as described above, since each terminal device needs to notify the base station device of reception status information regarding each channel using an uplink control channel or the like, reception is performed in proportion to the number of terminal devices and the number of channels. There was a problem that the amount of state information was enormous.
For this reason, there is a method for notifying only the average value of the reception states of all channels for each terminal device (Non-Patent Document 1), and a reception state information compression method using discrete cosine transform (DCT) (non-patent document 1). Patent Document 4, Non-Patent Document 5, Non-Patent Document 6).

Here, an example when the reception state measurement result is subjected to discrete cosine transform DCT processing is shown. FIG. 26 is a diagram illustrating an example of a reception state measurement result, and FIG. 27 is a diagram illustrating an example of a result obtained by performing a discrete cosine transform DCT process on the reception state measurement result illustrated in FIG. In FIG. 26, reception state measurement results are shown in correspondence with channel numbers. In FIG. 27, the sample value after the discrete cosine transform DCT process that represents the result (signal component) obtained by performing the discrete cosine transform DCT process on the reception state measurement result is shown in correspondence with the sample number.
As shown in FIG. 27, the signal components after the discrete cosine transform DCT processing are collected in the low frequency region, and the components having a high frequency are very small values (values close to zero). In Non-Patent Document 4, using such a property, a method of compressing reception state information by feeding back only a low-frequency component without feeding back a high-frequency component of a signal after discrete cosine transform DCT. Show. In the base station apparatus, after receiving the reception state information compressed in this way, by inserting zeros into the sample points of the deleted high frequency components and performing an inverse discrete cosine transform (IDCT: Inverse Discrete Cosine Transform) process, The reception state observed on the receiving side can be reproduced without being greatly affected by the deleted high frequency component.

Further, in Non-Patent Document 5 and Non-Patent Document 6, a point in a low frequency region used for generating reception state information compressed after discrete cosine transform DCT processing according to a propagation path environment such as delay dispersion and receiver speed. It is mentioned that reception state information compressed according to the propagation path can be generated by changing the number.
Kishiyama et al. "Experimental results of throughput characteristics of adaptive modulation / demodulation and channel coding in downlink VSF-OFCDM broadband wireless access", IEICE Technical Report, May 2003, RCS 2003-25 Maehara et al. “Examination of OFDM / TDD Transmission Method Using Subcarrier Adaptive Modulation”, 2001 IEICE General Conference, March 2001, B-5-100, p. 498 “CQI report and scheduling procedure”, 3GPP, TSG-RAN WG1 Meeting # 42bis, R1-051045, October 2005 “DCT based CQI reporting scheme”, 3GPP, TSG RAN WG1 ad hoc meeting on LTE, R1-060228 “Sensitivity of DL / UL Performance to CQI Compression with Text Proposal”, 3GPP, TSG RAN WG1 ad hoc meeting on LTE, R1-061777 “E-UTRA Incremental CQI Reporting Using DCT Coding”, 3GPP, TSG RAN WG2 # 55, R2-062858

However, the above-described conventional system has a problem that it is impossible to achieve both reduction in the amount of reception state information and achievement of excellent transmission efficiency.
For example, in the method of reporting only the average value of the reception states of all channels, it is not possible to perform scheduling for assigning terminal devices to channels with good reception states using the frequency selectivity of the propagation path. There is a problem that efficiency is lowered. Also, in this method, adaptive modulation according to the reception state of each channel cannot be performed, so the transmission rate is too low for a channel with a better reception state than the average value, resulting in inefficiency, and the reception state is worse than the average value. There is a problem that the error rate characteristic deteriorates in the channel.
Furthermore, in the reception state information compression method using the discrete cosine transform DCT, the amount of information can be reduced to some extent, but the generation of compressed reception state information after the discrete cosine transform DCT processing is based only on the change of the propagation path environment. In order to determine the number of sample points in the low frequency region used for the transmission, detailed reception status information is notified even to terminal devices that do not require detailed reception status information for each channel, which is inefficient due to the amount of extra information. There's a problem.

The present invention has been made in view of such circumstances, and its object is good and scheduling transmission efficiency, the base station apparatus capable of compatibility between notification efficient reception state information, radio communications A system, a reception state notification method, and a program are provided.

  The present invention has been made to solve the above-described problem, and the base station apparatus of the present invention allocates a channel used when transmitting transmission data to the terminal apparatus based on the reception state information received from the terminal apparatus. In the base station device, one of the terminal devices is selected from a plurality of lossy compression methods having different compression ratios based on a data amount index that is a value serving as a data amount index of the transmission data transmitted to each of the terminal devices. A request generation unit that generates, for each of the terminal devices, notification request information indicating a request for reception state information obtained by selecting one lossy compression method, and compressing information indicating a reception state by the selected lossy compression method; And a request transmission unit that transmits the generated notification request information.

  Thereby, when the base station apparatus selects the lossy compression method of the reception state information requested by each of the terminal apparatuses, the base station apparatus transmits the entire system by scheduling based on the data amount index for each terminal apparatus. It is determined whether or not the terminal device can be expected to have an effect of increasing efficiency. For a terminal device that can be expected to have an effect, a lossy compression method with a low compression rate that enables more efficient scheduling, and a terminal device that has less expected effect Is an irreversible compression method that provides the minimum amount of information, that is, a irreversible compression method with a high compression ratio, so that it is possible to suppress the data amount of reception status information while increasing the transmission efficiency. It is possible to achieve both excellent scheduling and efficient notification of reception status information.

  Further, the base station apparatus of the present invention is the above-described base station apparatus, wherein the request generation unit has a lower compression rate than the lossy compression method as the amount of data represented by the data amount index increases. A reversible compression method is selected.

  As a result, when the base station device selects the lossy compression method of the reception state information requested by the request generation unit for each of the terminal devices, the terminal device with the larger amount of data represented by the data amount index performs the entire system through scheduling. Therefore, it is expected to increase the transmission efficiency and improve the data volume of the reception status information by using a lossy compression method with a low compression rate that can be effectively scheduled for a terminal device with a large amount of data. Therefore, it is possible to achieve both scheduling with excellent transmission efficiency and efficient notification of reception status information.

  The base station apparatus of the present invention is any one of the above base station apparatuses, wherein each of the lossy compression methods includes conversion by discrete cosine transform, and the discrete cosine transform is performed by the lossy compression method. Among the sample values as a result, the number of sample points of the sample value used for the reception state information is different.

  Thereby, when the base station apparatus selects the lossy compression method of the reception state information requested by each of the terminal apparatuses, the base station apparatus transmits the entire system by scheduling based on the data amount index for each terminal apparatus. It is determined whether or not the terminal device can be expected to increase efficiency, and for a terminal device that can be expected to be effective, the lossy compression method with a large number of sample points of sample values that can be more efficiently scheduled is expected to have the expected effect. For a small number of terminal devices, the lossy compression method that provides the minimum amount of information, that is, the lossy compression method with a small number of sample points, reduces the amount of data in the reception status information while increasing the transmission efficiency. Therefore, it is possible to achieve both scheduling with excellent transmission efficiency and efficient notification of reception status information. It can become.

  The base station apparatus according to the present invention is any one of the above-described base station apparatuses, wherein each of the lossy compression methods includes conversion by quantization, and the quantization is performed by the lossy compression method. The number of quantization levels is different.

  Thereby, when the base station apparatus selects the lossy compression method of the reception state information requested by each of the terminal apparatuses, the base station apparatus transmits the entire system by scheduling based on the data amount index for each terminal apparatus. It is determined whether or not the terminal device can be expected to have an effect of increasing efficiency. For a terminal device that can be expected to have an effect, a lossy compression method with a large number of quantization levels that can be more efficiently scheduled is used, and a terminal that has less expected effect As for the device, it is possible to suppress the data amount of the reception state information while improving the transmission efficiency by adopting an irreversible compression method that obtains minimum information, that is, an irreversible compression method with a small number of quantization levels. Therefore, it is possible to achieve both scheduling with excellent transmission efficiency and efficient notification of reception state information.

  The base station apparatus of the present invention is the above-described base station apparatus, wherein each of the irreversible compression methods includes a discrete cosine transform and a transform by quantization, and the discrete cosine transform is performed by the irreversible compression method. This is characterized in that the number of quantization levels at the time of quantizing the sample value as a result of is different.

  Moreover, the base station apparatus of the present invention is any one of the above-described base station apparatuses, wherein the request generation unit is a value that serves as an index of frequency fluctuation in the reception state of the terminal apparatus in addition to the data amount index. One lossy compression method is selected for each terminal device based on the frequency fluctuation index.

  Thus, the base station apparatus performs scheduling based on the data amount index and the frequency fluctuation index for each terminal apparatus when determining the irreversible compression method of the reception state information requested by the request generation unit to each terminal apparatus. To determine whether or not the terminal device can be expected to increase the transmission efficiency of the entire system. For terminal devices with a small amount of data, a lossy compression method that can obtain minimum information, that is, a lossy compression method with a small data amount and a high compression rate, can improve the transmission efficiency and reduce the data amount of reception state information. Therefore, it is possible to achieve both scheduling with excellent transmission efficiency and efficient notification of reception status information.

  Moreover, the base station apparatus of the present invention is the above-described base station apparatus, wherein the request generation unit has a large amount of data represented by the data amount index and has a large frequency variation represented by the frequency variation index. The irreversible compression method having a low compression rate is selected.

  Also, the base station apparatus of the present invention is any one of the above base station apparatuses, wherein the frequency variation index is a delay dispersion of a propagation path between each terminal apparatus and the base station apparatus. And

  Thereby, when the base station apparatus determines the grouping method of the reception state information that the request generation unit requests from each terminal apparatus, the base station apparatus performs scheduling based on the data amount index and the time variation index for each terminal apparatus. It is determined whether or not the terminal device can be expected to increase the transmission efficiency of the entire system, and for a terminal device that can be expected to be effective, a lossy compression method with a low compression rate that enables more efficient scheduling can be expected. For a small number of terminal devices, a lossy compression method that provides the minimum amount of information, that is, a lossy compression method with a small amount of data and a high compression rate, suppresses the data amount of reception status information while increasing transmission efficiency. Therefore, it is possible to achieve both scheduling with excellent transmission efficiency and efficient notification of reception status information.

  Moreover, the base station apparatus of the present invention is any one of the above-described base station apparatuses, wherein the request generation unit is a value serving as an index of time variation of the reception state of the terminal apparatus in addition to the data amount index. One irreversible compression method is selected for each of the terminal devices based on the time variation index.

  Moreover, the base station apparatus of the present invention is the above-described base station apparatus, wherein the request generation unit has a large amount of data represented by the data amount index and has a small time variation represented by the time variation index. The irreversible compression method having a low compression rate is selected.

  Further, the base station apparatus of the present invention is any one of the above-described base station apparatuses, and the time variation index is a maximum Doppler frequency of a propagation path between each terminal apparatus and the base station apparatus. Features.

  Moreover, the base station apparatus of the present invention is any one of the above-described base station apparatuses, wherein the request generation unit is a value serving as an index of time variation of the reception state of the terminal apparatus in addition to the data amount index. One irreversible compression method is selected for each terminal device based on the time variation index and the frequency variation index, which is a value serving as an index of frequency variation in the reception state of the terminal device.

  The base station apparatus of the present invention is the above-described base station apparatus, wherein the request generation unit has a large amount of data represented by the data amount index, and a large frequency variation represented by the frequency variation index, and The terminal device having a smaller time variation represented by the time variation index selects an irreversible compression method having a lower compression rate.

  Further, the base station apparatus of the present invention is any one of the above base station apparatuses, wherein the time variation index is a maximum Doppler frequency of a propagation path between each terminal apparatus and the base station apparatus, The frequency variation index is characterized by delay dispersion of a propagation path between each terminal apparatus and the base station apparatus.

  A base station apparatus according to the present invention is any one of the above-described base station apparatuses, wherein the request generation unit selects an irreversible compression method having the highest compression rate for the first time.

  The base station apparatus of the present invention is any one of the above-described base station apparatuses, and includes a transmission buffer unit that accumulates communication data to be transmitted to each terminal apparatus, and the data amount index of one terminal apparatus is The amount of communication data to be transmitted to the one terminal device stored in the transmission buffer unit.

  Further, the base station apparatus of the present invention is any one of the above base station apparatuses, wherein the data amount index of one terminal apparatus is a bit rate of communication data to be transmitted to the one terminal apparatus. Features.

  Further, the base station apparatus of the present invention is any one of the above-described base station apparatuses, based on the reception state information, a reception unit that receives a signal including reception state information from each terminal device, and And a scheduling unit that generates a reception state in each channel of each terminal apparatus and allocates a channel to the transmission data based on the generated reception state in each channel of each terminal apparatus.

  Further, the base station apparatus of the present invention is any one of the above-described base station apparatuses, wherein the scheduling unit sequentially selects channels from transmission data addressed to a terminal apparatus for which the irreversible compression method having a low compression rate is selected. It is characterized by assigning.

  In addition, the terminal device of the present invention transmits reception state information to a base station device, and communicates with the base station device on a channel assigned by the base station device based on the reception state information. Received compressed by one irreversible compression method selected from a plurality of irreversible compression methods having different compression ratios based on a data amount index that is a value serving as an index of the amount of data transmitted by the device to the terminal device A request acquisition unit that acquires notification request information representing a request for state information from received data, and a reception state information generation unit that generates reception state information requested by the acquired notification request information, To do.

  The terminal device of the present invention is the above-described terminal device, wherein each of the irreversible compression methods includes conversion by discrete cosine transform, and a sample value that is a result of the discrete cosine transform by the irreversible compression method. Among them, the number of sample points of sample values used for the reception state information is different.

  The terminal device of the present invention is the above-described terminal device, wherein each of the irreversible compression methods includes conversion by quantization, and the number of quantization levels when performing the quantization by the irreversible compression method. Are different.

  Further, the terminal device of the present invention is the above-described terminal device, wherein each of the irreversible compression methods includes a discrete cosine transform and a transform by quantization, and the result of the discrete cosine transform by the irreversible compression method. The number of quantization levels at the time of quantizing the sample value is different.

  A radio communication system according to the present invention includes a radio that includes a terminal apparatus that transmits reception state information, and a base station apparatus that allocates a channel used when transmitting transmission data to the terminal apparatus based on the received reception state. In the communication system, the base station apparatus is based on a data amount index that is a value serving as an index of the data amount of the transmission data to be transmitted to each of the terminal apparatuses, from among a plurality of lossy compression methods having different compression rates. Request for generating, for each terminal device, notification request information indicating a request for reception state information obtained by selecting one lossy compression method for each terminal device and compressing information indicating the reception state by the selected lossy compression method. A generation unit, and a request transmission unit that transmits the generated notification request information, wherein the terminal device acquires the notification request information from received data. And resulting unit, characterized by comprising a reception state information generation unit for generating a reception status information the acquired notification request information requests.

  In addition, the reception state notification method of the present invention includes a terminal device that transmits reception state information, and a base station device that allocates a channel used when transmitting transmission data to the terminal device based on the received reception state. In a reception state notification method in a wireless communication system, a plurality of irreversible data having different compression ratios based on a data amount index that is a value that is an index of a data amount of the transmission data that the base station device transmits to each of the terminal devices One irreversible compression method is selected for each terminal device from among compression methods, and notification request information indicating a request for reception state information obtained by compressing information indicating a reception state by the selected irreversible compression method is transmitted to the terminal. A first process that is generated for each apparatus; a second process in which the base station apparatus transmits the generated notification request information; and the terminal apparatus that transmits the notification request information. A third process acquired from the received data, a fourth process in which the terminal device generates reception state information requested by the acquired notification request information, and the reception state information generated by the terminal device. And a fifth step of transmitting the information to the base station apparatus.

  Further, the program of the present invention provides the transmission data for transmitting to each of the terminal devices a computer provided in a base station device that allocates a channel for transmitting transmission data to the terminal device based on the reception state information received from the terminal device. Based on the data amount index, which is a value serving as an index of the data amount, information about the reception state is selected by selecting one irreversible compression method for each of the terminal devices from a plurality of irreversible compression methods having different compression rates. The notification request information indicating the request for the reception state information compressed by the selected irreversible compression method is operated as a request generation unit that generates for each terminal device, and a request transmission unit that transmits the generated notification request information.

  Further, the program of the present invention includes a computer provided in a terminal device that transmits reception state information to a base station device and communicates with the base station device on a channel assigned by the base station device based on the reception state information. Based on a data amount index that is a value serving as an index of the amount of data transmitted by the base station device to the terminal device, by one irreversible compression method selected from a plurality of irreversible compression methods having different compression rates The notification request information indicating the request for the compressed reception state information is operated as a request acquisition unit that acquires from the received data, and a reception state information generation unit that generates the reception state information requested by the acquired notification request information.

  According to the present invention, when the base station device selects the irreversible method of the reception state information requested by each of the terminal devices, the base station device performs scheduling based on the data amount index for each terminal device. It is determined whether or not the terminal device can be expected to increase the transmission efficiency of the terminal, and for the terminal device that can be expected to be effective, a lossy compression method with a low compression rate that can perform more efficient scheduling, and a terminal that has less expected effect As for the device, it is possible to suppress the data amount of the reception state information while improving the transmission efficiency by using the lossy compression method that can obtain the minimum information, that is, the type having a high compression rate and a small amount of data. Thus, it is possible to achieve both scheduling with excellent transmission efficiency and efficient notification of reception state information.

  In the following description of each embodiment, it is assumed that an OFDM system that is a multi-carrier communication system is assumed as a communication system, and adaptive modulation and adaptive scheduling (channel allocation) are performed for each channel composed of at least one subcarrier. However, the present invention is not limited to this. For example, the present invention can also be applied to an MC-CDMA (Multi Carrier-Code Division Multiple Access) system using a diffusion technique. The unit of adaptive modulation and adaptive scheduling to which the present invention can be applied is not limited to the case of a channel. For example, in SDMA (Space Division Multiple Access) such as MIMO (Multiple Input Multiple Output), a transmission antenna or eigenmode A system in which communication is performed using a plurality of channels, such as a plurality of channels indicated by CDMA, a plurality of code channels in CDMA, or a combination thereof, and the reception state may be different for each channel In the present invention, the present invention can be applied.

  Each embodiment described below assumes a cellular system, and describes an OFDM-based downlink from a base station apparatus to a terminal apparatus and an uplink that notifies reception state information from the terminal apparatus to the base station apparatus. However, it is not limited to this. Between the two wireless communication devices, the side that notifies the reception state information of the channel (the side having the reception state information transmission function) is the terminal device, and the transmission data to each terminal device is sent to each channel based on the notified reception state information The base station apparatus is the side that performs adaptive modulation (the side that performs the scheduling function). There may be a case where one wireless communication apparatus has both functions. In this specification, a wireless communication device is a device that performs wireless communication, and includes a base station device, a terminal device, a wireless device, a mobile terminal device, a mobile phone, and the like. The present invention is applied to wireless communication devices in which one of a plurality of wireless communication devices performs a scheduling function and adaptive modulation, and another wireless communication device can execute a reception state information transmission function. Can do.

  Also, in each of the following embodiments, a communication system adopting FDD composed of a base station device and a plurality of terminal devices, assuming an OFDM adaptive modulation system in downlink communication, uplink communication Assumes a system that does not perform OFDM and adaptive modulation, but is not limited thereto.

  In the following description of each embodiment, it is assumed that an index calculated based on a pilot symbol, for example, a carrier power to noise power ratio CNR is used as reception state information. Other indicators such as RSSI (Received Signal Strength Indicator), SNR, SIR, SINR, CIR, CINR, and the like indicating the reception state in relation to received signal power and carrier power may be used. Also, modulation parameters such as MCS (Modulation and Coding Scheme), which is a combination of a modulation method and a channel coding rate, and a transmission rate may be used as reception state information.

[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
In the present embodiment, a case will be described where the base station apparatus determines an irreversible compression method using discrete cosine transform when each terminal apparatus reports a reception state based on the amount of downlink transmission data addressed to each terminal apparatus. To do.

  FIG. 1 is a diagram illustrating an example of a downlink subframe configuration in the present embodiment. As shown in FIG. 1, the channel in this embodiment means one or a plurality of subcarriers. Here, the subframe means a transmission unit, and this is a range in which a channel is allocated in one scheduling process. Further, the subframe is divided into T pieces (T is a natural number) with a predetermined time length TTI (Transmission Time Interval) in the time axis direction, and one TTI in one channel is set as a scheduling unit (hereinafter referred to as a resource block). The case will be described.

  The details of one of the resource blocks transmitted first in the subframe are shown in the upper right of FIG. One channel is divided into 10 subcarriers, and one TTI is divided into 10 OFDM symbols. In the first OFDM symbol in this resource block, pilot symbols are arranged on subcarriers having the minimum and maximum frequencies, and two pilot symbols are arranged at equal intervals. A downlink control information symbol is arranged in a subcarrier in which no pilot symbol is arranged. Downlink control information symbols are arranged on all subcarriers of the second OFDM symbol. Data symbols are arranged in the third and subsequent OFDM symbols. However, pilot symbols are arranged on the second, fifth, and eighth subcarriers from the lowest frequency of the fifth OFDM symbol, and on the third, sixth, and ninth subcarriers of the ninth OFDM symbol. Are arranged with pilot symbols.

  Further, the lower right part of FIG. 1 shows details of resource blocks transmitted after the second. This resource block is substantially the same as the resource block described above, but no downlink control information symbol is arranged, and a data symbol is arranged instead. Note that the scope of application of the present invention is not limited to the subframe configuration of FIG. 1, and in a system that performs communication using a plurality of channels, the reception status of each channel in each terminal device may be different. In contrast, the present invention is applicable.

  FIG. 2 is a schematic block diagram showing the configuration of the base station apparatus 200 in the present embodiment. The base station apparatus 200 includes a transmission buffer unit 201, an encoding unit 202, a mapping unit 203, an IFFT (Inverse Fast Fourier Transformation) unit 204, a GI (Guard Interval) insertion unit 205, a D / A (Digital-to-Analog) conversion unit 206, wireless transmission unit 207, antenna unit 208, wireless reception unit 209, A / D (Analog-to-Digital) conversion unit 210, demapping unit 211, decoding unit 212, notification A request determination unit 213, a scheduling unit 214, a downlink control information generation unit 215, a pilot generation unit 216, and a reception state information storage unit 217 are provided.

  First, the procedure in which the base station apparatus 200 transmits a downlink signal will be described with reference to FIG. The procedure for receiving the reception status information will be described later. The transmission buffer unit 201 accumulates the input transmission data in a buffer for each transmission destination terminal device 300 (FIG. 3), and sends a notification request for information on the amount of transmission data addressed to each terminal device 300 accumulated in the buffer. The data is output to the determination unit 213. The information on the transmission data amount output from the transmission buffer unit 201 is a value that serves as an index of the data amount transmitted to each terminal device 300 in the present embodiment. The notification request determination unit (request generation unit) 213 is irreversible using discrete cosine transform DCT for each terminal device 300 based on the transmission data amount information addressed to each terminal device 300 from the transmission buffer unit 201. Reception state information (hereinafter referred to as “DCT1 reception state information”) obtained by compressing the reception state of all channels by the compression method 1, and a lossy compression using a discrete cosine transform DCT having a higher compression rate than the lossy compression method 1. It is determined which type of reception status information is requested to be notified, including reception status information (hereinafter referred to as “DCT2 reception status information”) obtained by compressing the reception status of all channels by the method 2, and the reception status that is the determination result Information indicating the type of information is output to the downlink control information generation unit 215 as notification request information.

  Here, all channels represent all channels to which transmission data addressed to each terminal device 300 may be assigned with respect to each terminal device 300, and for example, all channels included in the frequency band used for the downlink Channels, all channels included in a part of the downlink frequency band determined with the base station apparatus 200 as a band to be received by each terminal apparatus 300, or all that each terminal apparatus 300 requests to allocate Represents a channel or the like. The same applies to the following embodiments. Details of the irreversible compression method and notification request information determination procedure will be described later.

  The scheduling unit 214 reads out the reception state information notified from each terminal device 300 stored in the reception state information storage unit 217, and receives the reception in each channel of each terminal device 300 from the reception state information notified from each terminal device 300. Generate a value representing the state. Here, as a method of generating a value representing the reception state in each channel of each terminal device 300 from the reception state information notified from each terminal device 300, reception compressed by the lossy compression method 1 or the lossy compression method 2 is performed. For the state information, a value representing the reception state in all channels is calculated by inserting zeros into the sample points of high frequency components deleted during compression and performing inverse discrete cosine transform IDCT processing. Next, the scheduling unit 214 assigns (schedules) the terminal device 300 to each resource block of each channel based on the calculated value indicating the reception state, selects a modulation parameter to be used in each resource block, and A scheduling result (scheduling information) and a modulation parameter selection result (modulation parameter information) are output. Note that the scheduling unit 214 may further perform scheduling based on transmission data amount information from the transmission buffer unit 201. Details of the operation of the scheduling unit 214 will be described later.

  The downlink control information generation unit (request transmission unit) 215 generates and outputs downlink control information including notification request information from the notification request determination unit 213 and scheduling information and modulation parameter information from the scheduling unit 214. Note that the terminal 300 with the same notification request information as the previous notification request information may be configured not to be included in the downlink control information. Also, for example, for one of the notification request information of the DCT1 reception state information and the notification request information of the DCT2 reception state information, a bit is assigned to the downlink control information for the request notification information related to the terminal device 300 of the corresponding destination. There may be no configuration.

  The encoding unit 202 reads the necessary amount of transmission data addressed to each terminal device 300 from the transmission buffer unit 201 according to the allocation information (scheduling information) of each terminal device 300 to the downlink notified from the scheduling unit 214, and further performs scheduling. Error correction coding processing is performed on transmission data addressed to each terminal apparatus 300 according to the modulation parameter information and scheduling information notified from unit 214, and a data sequence is generated and output. Pilot generation section 216 generates and outputs a parrot sequence that is a sequence of pilot symbols to be inserted into a transmission signal for reception state measurement in terminal apparatus 300.

  Mapping section 203 maps each bit of the data sequence output from encoding section 202 to a modulation symbol on a subcarrier based on modulation parameter information and scheduling information notified from scheduling section 214, and a downlink control information generation section The downlink control information generated in 215 and the pilot sequence generated in pilot generation section 216 are mapped to predetermined modulation symbols on predetermined subcarriers and output. For example, in the example of FIG. 1, the data sequence is mapped to the data symbol in the figure based on the scheduling information, the pilot sequence is mapped to the predetermined pilot symbol in the figure, and the downlink control information is the predetermined downlink control in the figure. Each is mapped to an information symbol.

  IFFT section 204 performs inverse fast Fourier transform IFFT processing on the modulation symbol sequence output from mapping section 203 to convert it into a time-axis OFDM signal, and outputs the converted signal to GI insertion section 205. The GI insertion unit 205 adds a guard period GI to the OFDM signal generated by the IFFT unit 204. The D / A conversion unit 206 converts the signal added with the guard period GI into an analog signal. The radio transmission unit 207 up-converts the analog signal and transmits it as a downlink signal from the antenna unit 208 to the terminal device 300.

FIG. 3 is a schematic block diagram showing the configuration of the terminal device 300 in the present embodiment.
The terminal device 300 includes an antenna unit 301, a radio reception unit 302, an A / D conversion unit 303, a GI removal unit 304, an FFT (Fast Fourier Transformation) unit 305, a demapping unit 306, a decoding unit 307, and a reception A state measurement unit 308, a reception state information generation unit 309, an encoding unit 310, a mapping unit 311, a D / A conversion unit 312, a wireless transmission unit 313, and a demodulation control unit 314 are provided.

  An operation in which the terminal apparatus 300 receives a downlink signal will be described with reference to FIG. Radio receiving section 302 receives the signal transmitted from base station apparatus 200 via antenna section 301, and down-converts it. The A / D conversion unit 303 converts the analog signal down-converted by the wireless reception unit 302 into a digital signal. The GI removal unit 304 removes the guard period GI from the digital signal, and outputs the OFDM signal from which the guard period GI is removed to the FFT unit 305. The FFT unit 305 converts the OFDM signal output from the GI removal unit 304 into a modulation symbol sequence by performing a fast Fourier transform FFT. Demapping section 306 first separates pilot symbols from the modulation symbol sequence output from FFT section 305 and outputs the pilot symbols to reception state measurement section 308. Next, the downlink control information is demapped and output to the demodulation control unit 314. Further, the data sequence is demapped according to the scheduling information and modulation parameter information from demodulation control section 314 and output to decoding section 307. Note that channel compensation may be performed on the modulation symbol sequence based on the pilot symbols.

  Decoding section 307 performs error correction decoding processing on the data sequence output from demapping section 306 according to the scheduling information and modulation parameter information output from demodulation control section 314, and outputs received data. The demodulation control unit (request acquisition unit) 314 uses the downlink control information input from the demapping unit 306 to determine scheduling information (information about a channel allocated to transmission data addressed to the terminal device 300), modulation parameter information (the allocated parameter). Information on the modulation parameter of the received channel) and the notification request information, and the scheduling information and the modulation parameter information are output to the demapping unit 306 and the decoding unit 307, and the notification request information is output to the reception state information generating unit 309.

  In addition, when the downlink control information is previously error-correction encoded in the base station apparatus 200, the demodulation control unit 314 performs error correction decoding. Also, in a system in which the base station apparatus 200 does not notify the notification request information to the terminal apparatus 300 whose notification request information is the same as the previous one, when the notification request information addressed to the terminal apparatus does not exist in the downlink control information The reception state information generation unit 309 is instructed to generate the same type of reception state information as that notified to the base station apparatus 200 last time. Further, in a system in which the base station apparatus 200 does not assign a bit to the downlink control information for one of the DCT1 reception state information notification request information and the DCT2 reception state information notification request information, the base station device 200 includes the downlink control information. When there is no notification request information addressed to the own terminal device 300, the reception state information generation unit 309 is instructed to generate corresponding reception state information.

  Next, a procedure in which terminal apparatus 300 feeds back reception state information to base station apparatus 200 will be described using FIG. The reception state measurement unit 308 measures the reception state in each channel by calculating the carrier power to noise power ratio CNR in each channel from the pilot symbols output from the demapping unit 306, and receives the reception state measurement result. It outputs to the state information generation part 309. In this embodiment, the case where the reception state is measured using pilot symbols will be described. However, the reception state may be measured using data symbols, or reception may be performed using the error correction decoding determination result of the received data. The state may be measured. Based on the notification request information output from the demodulation control unit 314, the reception status information generation unit 309, when the notification request information is information requesting DCT1 reception status information, each reception status measurement unit 308 outputs By performing a discrete cosine transform DCT process on the reception state measurement result in the channel, the sample value of the sample point based on the lossy compression method 1 is calculated, and reception state information representing the calculation result is generated. If the notification request information is information for requesting DCT2 reception state information, the reception state measurement result in each channel output from the reception state measurement unit 308 is subjected to discrete cosine transform DCT processing, whereby the lossy compression method 2 is performed. A sample value of a sample point based on the calculated value is calculated, and reception state information representing the calculation result is generated and output. That is, the reception state information generation unit 309 generates reception state information obtained by compressing information representing the reception state in each channel by applying an irreversible compression method with different compression rates based on the notification request information.

  Encoding section 310 performs error correction encoding on transmission data to base station apparatus 200 and outputs a data sequence. The mapping unit 311 maps the reception state information generated by the reception state information generation unit 309 and the data series output from the encoding unit 310 to modulation symbols and outputs the modulation symbols. The reception state information may be notified to the base station apparatus 200 separately from the transmission data to the base station apparatus 200. The D / A conversion unit 312 converts the signal output from the mapping unit 311 into an analog signal. The radio transmission unit 313 up-converts the converted analog signal and transmits the converted analog signal from the antenna unit 301 to the base station apparatus 200.

  Next, the procedure in which the base station apparatus 200 receives the reception state information transmitted from the terminal apparatus 300 will be described using FIG. The signal transmitted from the terminal device 300 is received by the wireless reception unit 209 via the antenna unit 208 and down-converted. The A / D converter 210 converts the down-converted analog signal into a digital signal and outputs the digital signal to the demapping unit 211. The demapping unit 211 demaps the digital signal (modulation symbol) sent from the A / D conversion unit 210, separates the reception state information and the data series, and sends the reception state information to the reception state information storage unit 217. Each data series is output to decoding section 212. Decoding section 212 performs error correction decoding on the data series extracted by demapping section 211 and extracts received data. The reception status information storage unit 217 stores the reception status information notified from each terminal device 300 separated by the demapping unit 211 for each terminal device 300 and outputs it in response to a request from the scheduling unit 214.

Next, details of the irreversible compression methods 1 and 2 including the discrete cosine transform DCT process and performed by the reception state information generation unit 309 will be described. FIG. 4 shows an example of sample values at each sample point when the lossy compression method 1 is used, and FIG. 5 shows an example of sample values at each sample point when the lossy compression method 2 is used. It shows corresponding to.
In the example shown in FIG. 4 and FIG. 5, both the irreversible compression method 1 and the irreversible compression method 2 are used when the sample values at the sample points only in the low frequency region are calculated by performing discrete cosine transform on the reception state. This is a lossy compression method. The lossy compression method 1 calculates sample values at 32 sample points from the low frequency region side, and the lossy compression method 2 calculates sample values at 16 sample points from the low frequency region side. That is, the information amount of the reception state information output from the reception state information generation unit 309 is that the notification request information requests the DCT1 reception state information compared to the case where the notification request information is information requesting the DCT2 reception state information. The case of information is larger.

  Next, an example of the reception state in each channel generated by the scheduling unit 214 from the reception state information compressed using the lossy compression method 1 and the reception state information compressed using the lossy compression method 2 They are shown in FIGS. 6 and 7, respectively. As can be seen from FIG. 6, the reception state G2 in each channel generated from the DCT1 reception state information, which is the reception state information compressed using the lossy compression method 1, is the same as the reception state measurement result G1 in each channel. I'm doing it. On the other hand, as shown in FIG. 7, the reception state G4 in each channel generated from the DCT2 reception state information which is the reception state information compressed using the lossy compression method 2 is the reception state measurement result G3 in each channel. It can be seen that they are not very consistent and represent an approximate variation in the channel direction. As described above, the lossy compression method 1 having a larger number of sample points for calculating the sample value has a larger amount of reception state information than the lossy compression method 2 having a smaller number of sample points for calculating the sample value. And the accuracy of the reception state in each channel generated from the reception state information is high.

  In the above description, an example is given in which the total number of channels is 64, and the number of sample points for calculating sample values in the lossy compression method 1 and the lossy compression method 2 is 32 and 16, respectively. These parameters may be other numbers as long as the number of sample points in the lossy compression method 1 is set larger than the number of sample points in the lossy compression method 2. For example, the total number of channels may be 100. Also, for example, the number of sample points for calculating the sample value may be one (if the number of sample points is 1, the sample value matches the average value of the reception state measurement results in all channels, A sample value can be calculated by a process of averaging reception state measurement results instead of the discrete cosine transform DCT process. When the scheduling unit 214 generates a reception state of each channel, each of the reception states of each channel is Alternatively, sample values may be calculated for all sample points.

  Also, here, a case has been described in which the amount of information of the reception state information is made different by setting the number of sample points to be different between the lossy compression method 1 and the lossy compression method 2. The information generation unit 309 quantizes the sample value which is the processing result of the discrete cosine transform DCT process, and sets the number of quantization levels at the time of the quantization to be different depending on the method, thereby receiving state information It is also possible to vary the amount of information. For example, in both the lossy compression method 1 and the lossy compression method 2, the number of sample points for calculating the sample value is set to 32, and the sample value at each sample point of the lossy compression method 1 is quantized with a quantization bit number of 8 bits. The sample value at each sample point of the lossy compression method 2 is quantized with a quantization bit number of 4 bits. As a result, similarly to the case where the number of sample points is set differently, the lossy compression method 1 has a larger amount of reception state information than the lossy compression method 2, and is calculated from the reception state information. It is possible to add a feature that the accuracy of the reception state in each channel is high.

In this example, the number of sample points is set to 32 for both the lossy compression method 1 and the lossy compression method 2, the sample value of the lossy compression method 1 is 8 bits, and the sample value of the lossy compression method 2 is 4 bits. However, it is needless to say that these parameters may be other numbers. It is sufficient that the number of quantization levels in the lossy compression method 1 is set larger than the number of quantization levels in the lossy compression method 2.
Furthermore, as a combination of these, the number of sample points and the number of quantization levels can be set differently in the lossy compression method 1 and the lossy compression method 2. Further, the number of quantization levels may be set to be different depending on sample points. The lossy compression method 1 has a feature that the amount of reception state information is larger than the lossy compression method 2 and the accuracy of the reception state in each channel generated from the reception state information is high. Each lossy compression method can be set.
In the present embodiment, in the lossy compression methods 1 and 2, it has been described that the quantization is performed after the discrete cosine transform DCT process is performed. However, the discrete cosine transform DCT process is performed after the quantization is performed. May be.
Further, in the irreversible compression methods 1 and 2, the values representing the reception state may be quantized without performing the discrete cosine transform DCT process.

  Next, details of the notification request information determination operation in the notification request determination unit 213, that is, the selection operation of the requested reception state information will be described with reference to FIG. FIG. 8 is a flowchart showing an example of the operation for determining the notification request information in this embodiment. First, the notification request determination unit 213 acquires the transmission data amount addressed to each terminal device 300 from the transmission buffer unit 201 (S801), and performs the following step S803 for each terminal device 300 (first to Nth terminal devices 300). The subsequent processing is repeated (loop from S802 to S806). For each terminal device 300, the notification request determination unit 213 compares the amount of transmission data addressed to the terminal device 300 with a predetermined threshold (S803), and if the amount of transmission data is equal to or greater than the predetermined threshold, the terminal device Select to request DCT1 reception status information from 300 (S804). If the amount of transmission data is less than a predetermined threshold, select to request DCT2 reception status information from the terminal device 300. (S805).

The predetermined threshold used for comparison in step S803 is determined in advance by the average value of the amount of transmission data addressed to all terminal devices 300, the number of terminal devices that notify DCT1 reception state information, and the number of terminal devices that notify DCT2 reception state information. The ratio of the number of terminal devices such that the total amount of reception status information notified from all the terminal devices 300 according to the notification request information is equal to or less than a predetermined value is realized. It is preferable to use a value or the like. However, the value is not limited to this, and any value that is greater than 0 and equal to or less than the maximum transmission data amount per terminal device 300 that can be stored in the transmission buffer unit 201 may be used.
In the present embodiment, it has been described that the request for DCT1 reception state information or the request for DCT2 reception state information is determined by comparing the threshold and the transmission data amount. The terminal device 300 having a large amount of transmission data is determined to be the DCT1 reception state information, such as the DCT1 reception state information, and the others are the DCT2 reception state information. Good.

  Next, details of the scheduling operation and the modulation parameter selection operation in the scheduling unit 214 will be described with reference to FIG. FIG. 9 is a flowchart illustrating an example of a scheduling operation and a modulation parameter selection operation in the present embodiment. The scheduling unit 214 reads the reception state information notified from each terminal device 300 from the reception state information storage unit 217 (S901). First, the scheduling unit 214 generates a value representing the reception state in each channel for each terminal device 300 from the read reception state information (S902). Next, the scheduling unit 214 allocates transmission data to be transmitted to each terminal device 300 to resource blocks based on a value indicating the generated reception state of each channel of each terminal device 300, that is, performs scheduling (S903). ). For each resource block allocated in step S903, the scheduling unit 214 selects a modulation parameter based on a value representing a reception state generated in the channel of the terminal device 300 allocated to each resource block (S904). Then, a scheduling result (scheduling information) and a modulation parameter selection result (modulation parameter information), which are allocation results to the resource block, are output (S905).

  FIG. 10 is a flowchart showing an example different from FIG. 9 of the scheduling operation and the modulation parameter selection operation in the present embodiment. The scheduling unit 214 reads the reception state information notified from each terminal device 300 from the reception state information storage unit 217 (S1001). The scheduling unit 214 generates a value representing a reception state in each channel of each terminal device 300 from the read reception state information (S1002). The scheduling unit 214 first allocates transmission data to be transmitted to each terminal device 300 that has notified the DCT1 reception state information to resource blocks based on values representing reception states generated in the respective channels of each terminal device 300 ( S1003) For each resource block assigned in step S1003, a modulation parameter is selected based on a value representing the reception state generated in the channel of the terminal device assigned to each resource block (S1004). The scheduling unit 214 assigns transmission data to be transmitted to each terminal apparatus 300 that has next notified the DCT2 reception state information in step S1003 based on a value representing the reception state generated in each channel of each terminal apparatus 300. Assigned to the remaining resource blocks (S1005), for each resource block assigned in step S1005, a modulation parameter is selected based on a value representing the generated reception state of each terminal device 300 assigned to each resource block (S1006). Finally, the scheduling unit 214 outputs a scheduling result (scheduling information) and a modulation parameter selection result (modulation parameter information), which are allocation results to resource blocks (S1007).

  As shown in FIG. 10, the terminal device that has notified the reception state information of the lossy compression method having a large number of sample points or a large number of quantization levels and a low compression rate in the order of DCT1 reception state information and DCT2 reception state information. By scheduling with priority from 300, the terminal device 300 having a large amount of downlink transmission data addressed to the terminal device 300, which can obtain excellent transmission efficiency, is preferentially scheduled to obtain excellent transmission efficiency as a whole system. Can do.

  As described above, according to the present embodiment, when the reception state information is notified from the plurality of terminal apparatuses 300 to the base station apparatus 200, the number of sample points is set according to the amount of downlink transmission data addressed to each terminal apparatus 300. DCT1 reception state information using the lossy compression method 1 with a large number or a large number of quantization levels as the reception state of all channels is notified, or the lossy compression method 2 with a small number of sample points or a small number of quantization levels Select whether to notify the DCT2 reception state information used for the reception state of the channel. Therefore, for a terminal device 300 that needs to allocate many resource blocks in the downlink and transmit a large amount of transmission data, since the number of sample points is large or the number of quantization levels is large, a detailed reception state of each channel is obtained. Therefore, efficient scheduling and adaptive modulation based on the detailed reception state of each channel can be preferentially performed, and efficient transmission can be realized.

On the other hand, for terminal devices 300 with relatively little data to be transmitted in the downlink, the number of sample points is small or the number of quantization levels is small, so that reception status information to be notified from those terminal devices 300 using the uplink The amount of information can be reduced.
As described above, the entire system realizes efficient reception state information notification by suppressing the total amount of uplink reception state information notification from each terminal device 300 and requires high-speed and large-capacity communication. By applying efficient scheduling and adaptive modulation to the terminal device 300, the efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system can be realized.

[Second Embodiment]
The second embodiment of the present invention will be described below with reference to the drawings. In this embodiment, based on the amount of downlink transmission data addressed to each terminal apparatus and the delay dispersion of the propagation path in each terminal apparatus, the irreversible compression method used when each terminal reports the reception state is determined.
FIG. 11 is a schematic block diagram illustrating the configuration of the base station device 1100 in the present embodiment. Note that the terminal device 300 in the present embodiment has the same configuration as that of the terminal device 300 in the first embodiment.

  In the first embodiment, a case has been described in which the amount of transmission data in the transmission buffer unit 201 is referred to when determining reception state information to be notified from the base station device 200 to each terminal device 300. When the base station apparatus 1100 according to the present embodiment determines the reception state information to be notified from the base station apparatus 1100 to each terminal apparatus 300, the transmission data amount and delay dispersion measurement section 1118 in the transmission buffer section 201 measures. The propagation path delay dispersion between the base station device 1100 and each terminal device 300 is referred to. In the present embodiment, a pilot signal is included in the uplink signal from each terminal apparatus 300, and the delay dispersion for each terminal apparatus 300 is measured in the base station apparatus 1100 using this. For this reason, the base station apparatus 1100 includes the delay dispersion measuring unit 1118, and among the functional blocks of the base station apparatus 1100, a demapping unit 1111 corresponding to the demapping unit 211 of the base station apparatus 200, and a base station A notification request determination unit 1113 corresponding to the notification request determination unit 213 of the device 200 is different from that of the first embodiment. The other configurations of the base station apparatus 1100 and the terminal apparatus 300 are the same as those in the first embodiment (FIGS. 2 and 3), and the description thereof is omitted.

  In base station apparatus 1100 of FIG. 11, demapping section 1111 demaps the digital signal sent from A / D conversion section 210, and separates the reception status information, data sequence, and pilot sequence. Demapping section 1111 outputs the separated reception status information to reception status information storage section 217, the data sequence to decoding section 212, and the pilot sequence to delay dispersion measurement section 1118. Delay dispersion measuring section 1118 measures the delay dispersion from the pilot sequence separated by demapping section 1111 for each terminal apparatus 300 and outputs the measurement result to notification request determining section 1113. The delay dispersion is a value calculated by the following equation (1).

The notification request determination unit 1113 is a transmission buffer unit that is an indicator of the delay dispersion measurement result measured by the delay dispersion measurement unit 918 that is an indicator of frequency fluctuation in the reception state of the terminal device 300 and an amount of data transmitted to each of the terminal devices 300. Based on the transmission data amount information addressed to each terminal device 300 from 201, reception status information (DCT1 reception status information) using the lossy compression method 1 for the reception status of all channels for each terminal device 300, and , Which of the reception status information (DCT2 reception status information) using the lossy compression method 2 for the reception status of all channels is determined, and the downlink control information generation unit uses the determination result as notification request information. To 215. In the present embodiment, the lossy compression method 1 and the lossy compression method 2 use the same discrete cosine transform method as in the first embodiment. Details of the notification request information determination procedure will be described later.
In the present embodiment, the base station apparatus 1100 includes the delay dispersion measuring unit 1118. However, the terminal 300 includes the delay dispersion measuring unit 1118, and delays using a downlink pilot signal. The dispersion may be measured, and the delay dispersion measurement result may be reported from the terminal apparatus 300 to the base station apparatus 1100.

  Next, details of the notification request information determination operation in the notification request determination unit 1113 will be described with reference to FIG. FIG. 12 is a flowchart showing an example of the operation for determining the notification request information in this embodiment. First, the notification request determination unit 1113 acquires the amount of transmission data addressed to each terminal device 300 from the transmission buffer unit 201 (S1201), and then from the delay dispersion measurement unit 1118 between the base station device 1100 and each terminal device 300. A propagation delay measurement result is acquired (S1202). The notification request determination unit 1113 repeats the following processing for each terminal device 300 (first to Nth terminal devices 300) (loop from S1203 to S12008). For each terminal device 300, the notification request determination unit 1113 compares the transmission data amount addressed to the terminal device 300 with a predetermined first threshold value (S1204), and if the transmission data amount is equal to or greater than the predetermined first threshold value. Further, the delay dispersion measurement result for the terminal device is compared with a predetermined second threshold (S1205), and if the delay dispersion measurement result is equal to or greater than the predetermined second threshold, the DCT1 reception state information is transmitted to the terminal device 300. Is selected (S1206). When the transmission data amount is less than the predetermined first threshold value in the comparison of step S1204 or the delay dispersion measurement result is less than the predetermined second threshold value in the comparison of step S1205, the notification request determination unit 1113 Request to request DCT2 reception status information from 300 is selected (S1007).

The predetermined first threshold value is the same as the predetermined threshold value in the first embodiment, and the average value of the amount of transmission data addressed to all terminal devices 300, the number of terminal devices that notify DCT1 reception state information, and the DCT2 reception state The value determined so that the number of terminal devices that notify information is a predetermined ratio, and the total amount of reception status information notified from all terminal devices according to the notification request information is less than or equal to the predetermined value It is preferable to use a value that realizes the ratio of the number of terminal devices, but is not limited to this, and is not limited to this, and is less than the maximum transmission data amount per terminal device 300 that can be stored in the transmission buffer unit 201. Any value can be used.
Further, when the scheduling unit 214 generates a value representing the reception state of each channel from the reception state information compressed by the lossy compression method 2, the predetermined second threshold is generated in the reception state and reception state of each channel generated. Although it is preferable to use a value determined so that the difference from the reception state measurement result by the measurement unit 308 is equal to or less than a predetermined value, the value is not limited to this, and reception state information compressed by the lossy compression method 2 The difference between the reception state of each channel generated from the reception state and the reception state measurement result by the reception state measurement unit 308 is the difference between the reception state and reception state measurement of each channel generated from the reception state information compressed by the lossy compression method 1. Any delay dispersion value may be used as long as the difference from the reception state measurement result by the unit 308 is approximately the same value.

  In the above description, as an index indicating the difference between the reception state of each channel generated by the scheduling unit 214 and the reception state measurement result by the original reception state measurement unit 308, that is, as an index of frequency fluctuation of the reception state measurement result, Although the case where the delay dispersion of the propagation path between the base station apparatus 1100 and the terminal apparatus 300 is used has been described, the present invention is not limited to this. For example, the coherent bandwidth of the propagation path between the base station device 1100 and the terminal device 300, the maximum sample number where the sample value is less than or equal to a predetermined value, the sample value of the predetermined sample number and a predetermined value set in advance Of course, other indicators related to the dispersion (frequency fluctuation) of the reception state measurement result of each channel generated, such as the difference between the channels, may be used.

  Thus, according to the present embodiment, when notifying the reception state information from the plurality of terminal devices 300 to the base station device 1100, the amount of downlink transmission data addressed to each terminal device 300, each terminal device 300, and the base station According to the delay dispersion of the propagation path with the apparatus 1100, the DCT1 reception state information indicating the reception state of all channels is notified using the irreversible compression method 1 having a large number of sample points for calculating the sample value, It is selected whether to notify DCT2 reception status information representing the reception status of all channels using the lossy compression method 2 with a small number of sample points for calculating sample values. Therefore, for a terminal device 300 that needs to allocate many resource blocks in the downlink and transmit a large amount of transmission data, since the number of sample points is large, a detailed reception state of each channel can be obtained. Efficient scheduling and adaptive modulation based on detailed reception conditions can be preferentially performed, and higher-speed transmission can be realized. Furthermore, in order to reduce the number of sample points, the terminal devices 300 that can obtain a detailed reception state with a small number of sample points even if a large amount of transmission data needs to be transmitted. It is possible to reduce the amount of reception state information to be notified using a link.

On the other hand, since the number of sample points is small for the terminal device 300 with relatively little data to be transmitted on the downlink, the amount of reception state information to be notified from the terminal device 300 using the uplink is reduced. Can do.
As described above, the entire system realizes efficient reception state information notification by suppressing the total amount of uplink reception state information notification from each terminal device 300 and requires high-speed and large-capacity communication. By applying efficient scheduling and adaptive modulation to the terminal device 300, the efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system can be realized.

[Third Embodiment]
The third embodiment of the present invention will be described below with reference to the drawings. In this embodiment, based on the amount of downlink transmission data addressed to each terminal device and the maximum Doppler frequency fd in each terminal device, the irreversible compression method used when each terminal reports the reception state is determined.
FIG. 13 is a schematic block diagram showing the configuration of the base station device 1300 in the present embodiment. Note that the terminal device 300 in the present embodiment has the same configuration as that of the terminal device 300 in the first embodiment.

  In the first embodiment, a case has been described in which the amount of transmission data in the transmission buffer unit 201 is referred to when determining reception state information to be notified from the base station device 200 to each terminal device 300. When the base station device 1300 in the present embodiment determines the reception state information to be notified from the base station device 1300 to each terminal device 300, the transmission data amount in the transmission buffer unit 201 and the fd measurement unit 1319 measure each The Doppler frequency fd related to the terminal device 300 is referred to. In the present embodiment, a pilot signal is included in the uplink signal from each terminal apparatus 300, and using this, the base station apparatus 1300 measures the maximum Doppler frequency fd for each terminal apparatus 300. Therefore, the base station device 1300 includes the fd measurement unit 1319, and among the functional blocks of the base station device 1300, a demapping unit 1311 corresponding to the demapping unit 211 of the base station device 200, and the base station device A notification request determination unit 1313 corresponding to the 200 notification request determination unit 213 is different from that of the first embodiment. The other configurations of the base station apparatus 1100 and the terminal apparatus 300 are the same as those in the first embodiment (FIGS. 2 and 3), and the description thereof is omitted.

In base station apparatus 1100 of FIG. 13, demapping section 1311 demaps the digital signal (modulation symbol) sent from A / D conversion section 210, and separates the reception status information, data sequence, and pilot sequence. The demapping unit 1311 outputs the separated reception state information to the reception state information storage unit 217, the data sequence to the decoding unit 212, and the pilot sequence to the fd measurement unit 1319. The fd measurement unit 1319 measures the maximum Doppler frequency fd from the magnitude of the fluctuation in the time direction of the pilot sequence extracted by the demapping unit 1311 and outputs the measurement result of the maximum Doppler frequency fd. The notification request determination unit 1313 is a transmission buffer unit that is an index of a measurement result of the Doppler frequency fd measured by the fd measurement unit 1319 that is an index of time variation of the reception state of the terminal device 300 and an amount of data transmitted to each of the terminal devices 300. 201, reception state information (DCT1 reception state information) obtained by compressing the reception state of all channels using the lossy compression method 1 for each terminal device 300 based on the transmission data amount information addressed to each terminal device 300 from 201. ) And reception state information reception state information (DCT2 reception state information) obtained by compressing the reception state of all channels using the irreversible compression method 2, and determine the notification result as notification request information. To the downlink control information generation unit 215. Note that the lossy compression method 1 and the lossy compression method 2 use the same lossy compression method as in the first embodiment. Details of the notification request information determination procedure will be described later.
In the present embodiment, the base station apparatus 1300 includes the fd measurement unit 1319. However, the terminal apparatus 300 includes the fd measurement unit 1319, and the measurement result of the maximum Doppler frequency fd is obtained from the terminal. The apparatus 300 may report to the base station apparatus 1300.

  Next, details of the notification request information determination operation in the notification request determination unit 1313 will be described with reference to FIG. FIG. 14 is a flowchart showing an example of the operation for determining the notification request information in this embodiment. First, the notification request determination unit 1313 acquires the transmission data amount addressed to each terminal device 300 from the transmission buffer unit 201 (S1401), and acquires the measurement result of the maximum Doppler frequency fd for each terminal device 300 from the fd measurement unit 1319 ( S1402), the following processing is repeated for each terminal device 300 (first to Nth terminal devices 300) (loop from S1403 to S1408).

  For each terminal device 300, the notification request determination unit 1313 compares the transmission data amount addressed to the terminal device 300 with a predetermined first threshold value (S1404), and if the transmission data amount is equal to or greater than the predetermined first threshold value. Further, the measurement result of the maximum Doppler frequency fd in the terminal device 300 is compared with a predetermined third threshold (S1405), and if the measurement result of the maximum Doppler frequency fd is less than the predetermined third threshold, the terminal device 300 Is requested to request DCT1 reception status information (S1406). Further, the notification request determination unit 1313 determines that the transmission data amount is less than the predetermined first threshold value in the comparison in step S1404, or the measurement result of the maximum Doppler frequency fd is equal to or greater than the predetermined third threshold value in the comparison in step S1405. In this case, it is selected to request DCT2 reception state information from the terminal device 300 (S1407).

  The predetermined first threshold is the average value of the amount of transmission data addressed to all terminal devices 300, the DCT1 reception state, similarly to the predetermined threshold in the first embodiment and the predetermined first threshold in the second embodiment. The number of terminal devices for notifying information and the number of terminal devices for notifying DCT2 reception status information are set to a predetermined ratio, the reception status information notified from all terminal devices 300 according to the notification request information. It is preferable to use a value that realizes the ratio of the number of terminal devices so that the total amount of information is equal to or less than a predetermined value, but is not limited to this. Any value that is less than or equal to the maximum amount of transmission data per terminal device 300 may be used.

  Further, the predetermined third threshold is a time at which the terminal apparatus 300 measures the reception state, and a time at which the terminal apparatus 300 receives the transmission data that the base station apparatus 1300 performs scheduling / adaptive modulation based on the reception state measurement result. It is preferable to use a value determined so that the so-called processing delay, the so-called processing delay, coincides with the coherent time obtained by multiplying the reciprocal of the maximum Doppler frequency fd by a constant, but is not limited thereto. Between the reception state at the time when the terminal device 300 measures the reception state and the reception state at the time when the terminal device 300 receives the transmission data that the base station device 1300 receives scheduling / adaptive modulation based on the reception state measurement result Maximum Doppler circumference so that the fluctuation is within an acceptable range and the two reception states are almost the same value. Or if the value of the number fd.

  In the above description, a case where the maximum Doppler frequency fd in the terminal device 300 is used as an index indicating the speed of fluctuation of the reception state measurement result of the channel of each terminal apparatus 300, that is, as an index indicating time variation of the reception state. Although explained, it is not limited to this. For example, the terminal device 300 receives the coherent time in the terminal device 300, the reception state at the time when the terminal device 300 measures the reception state, and transmission data that the base station device 1300 performs scheduling / adaptive modulation based on the reception state measurement result. Other indicators related to the speed of fluctuation of the reception state measurement result of the channel of each terminal device 300, such as a difference from the reception state at the time to be performed and a value obtained by measuring the moving speed of the terminal device 300 may be used.

  Thus, according to the present embodiment, when notifying the reception state information from the plurality of terminal devices 300 to the base station device 1100, the amount of downlink transmission data addressed to each terminal device 300 and the maximum for each terminal device 300 are determined. Depending on the Doppler frequency fd, the lossy compression method 1 with a large number of sample points for calculating the sample value is used to notify DCT1 reception state information indicating the reception state of all channels, or the number of sample points for calculating the sample value It is selected whether to notify DCT2 reception status information indicating the reception status of all channels using the lossy compression method 2 with a small amount of data. Therefore, for a terminal device 300 that needs to allocate many resource blocks in the downlink and transmit a large amount of transmission data, since the number of sample points is large, a detailed reception state of each channel can be obtained. Efficient scheduling and adaptive modulation based on detailed reception conditions can be preferentially performed, and higher-speed transmission can be realized. Further, even when a large amount of transmission data needs to be transmitted, the terminal device 300 having a small effect of scheduling / adaptive modulation because the reception state of the channel changes rapidly and the reception state changes before and after the processing delay. In order to reduce the number of points, it is possible to reduce the amount of reception state information to be notified from the terminal apparatus 300 using the uplink.

On the other hand, for the terminal device 300 with relatively little data to be transmitted in the downlink, since the notification of DCT2 reception state information is requested, the number of sample points is small, so the terminal device 300 should be notified using the uplink. It is possible to reduce the amount of reception status information.
As described above, the entire system realizes efficient reception state information notification by suppressing the total amount of uplink reception state information notification from each terminal device 300 and requires high-speed and large-capacity communication. By applying efficient scheduling and adaptive modulation to the terminal device 300, the efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system can be realized.

[Fourth Embodiment]
In each of the above embodiments, a case has been described where one irreversible compression method is selected from two types of irreversible compression methods based on at least the transmission data amount, but not necessarily two types and more than two types. One lossy compression method may be selected from a number of lossy compression methods.
In this embodiment, based on the amount of downlink transmission data addressed to each terminal device, the irreversible compression method used when each terminal device reports the reception state is determined from among the three irreversible compression methods.

FIG. 15 is a schematic block diagram showing the configuration of the base station device 1500 in the present embodiment. In addition, the terminal device in this embodiment is realizable with the structure similar to the structure of the terminal device 300 in 1st Embodiment. In the first embodiment, when a notification request is sent from the base station apparatus 200 to each terminal apparatus 300, the DCT1 reception state information obtained by compressing the reception states of all channels by the lossy compression method 1 for each terminal apparatus 300 and The case has been described in which one of the DCT2 reception state information obtained by compressing the reception state of all channels by the lossy compression method 2 is selected.
In this embodiment, when making a notification request from the base station apparatus 1500 to each terminal apparatus 300, in addition to the DCT1 reception state information and the DCT2 reception state information, the lossy compression method 2 is used for each terminal apparatus 300. Also, one of the three types of reception status information of the reception status information (hereinafter referred to as “DCT3 reception status information”) obtained by compressing the reception status of all channels by the lossy compression method 3 having a high compression rate is selected. .

Of the functional blocks of the base station apparatus 1500 in the present embodiment, a notification request determination unit 1513 corresponding to the notification request determination unit 213 of the base station apparatus 200 and a scheduling unit 1514 corresponding to the scheduling unit 214 are the first embodiment. Is different. The other configurations of the base station apparatus 1500 and the terminal apparatus 300 are the same as those in the first embodiment (FIGS. 2 and 3), and the description thereof is omitted.
Details of the notification request information determination operation in the notification request determination unit 1513 in the base station apparatus 1500 will be described with reference to FIG. FIG. 16 is a flowchart showing an example of the operation for determining the notification request information in the present embodiment. First, the notification request determination unit 1513 acquires the amount of transmission data addressed to each terminal device 300 from the transmission buffer unit 201 (S1601), and performs the following processing for each terminal device 300 (first to Nth terminal devices 300). Repeat (loop from S1602 to S1608).

  The notification request determination unit 1513 compares the transmission data amount addressed to the terminal device 300 with a predetermined threshold a for each terminal device 300 (S1603). If the transmission data amount is equal to or greater than the predetermined threshold a, The amount of transmission data addressed to the terminal device 300 is compared with a predetermined threshold value b (S1604), and if the amount of transmission data is equal to or greater than the predetermined threshold value b, DCT1 reception state information is requested from the terminal device 300. Is selected (S1605). Further, the notification request determination unit 1313 determines that the terminal device 300 if the transmission data amount is equal to or larger than the predetermined threshold a in the comparison in step S1603 and the transmission data amount is smaller than the predetermined threshold b in the comparison in step S1604. Is requested to request DCT2 reception status information (S1606). If the transmission data amount is less than the predetermined threshold a in the comparison in step S1603, the notification request determination unit 1513 selects to request DCT3 reception state information from the terminal device 300 (S1607).

  The predetermined threshold value a and threshold value b are a predetermined ratio of the number of terminal devices that notify DCT1 reception state information, the number of terminal devices that notify DCT2 reception state information, and the number of terminal devices that notify DCT3 reception state information. A value that realizes the ratio of the number of terminal devices such that the total information amount of the reception state information notified from all the terminal devices 300 in accordance with the notification request information is equal to or less than a predetermined value, etc. However, the present invention is not limited to this, and any value that is greater than 0, less than or equal to the maximum amount of transmission data per terminal device that can be stored in the transmission buffer unit, and greater than threshold a is greater than threshold a. That's fine.

  Next, details of the scheduling operation and the modulation parameter selection operation in the scheduling unit 1514 will be described with reference to FIG. FIG. 17 is a flowchart illustrating an example of a scheduling operation and a modulation parameter selection operation in the present embodiment. The scheduling unit 1514 reads the reception state information notified from each terminal device 300 from the reception state information storage unit 217 (S1701), and generates a value representing the reception state in each channel of each terminal device 300 from the read reception state information. (S1702). Next, the scheduling unit 1514 first transmits the transmission data to be transmitted to each terminal apparatus 300 that has notified the DCT1 reception state information based on the value indicating the reception state generated in step S1702 in each channel of each terminal apparatus 300. Based on the value indicating the reception state generated in step S1702 in the corresponding channel of the terminal device 300 assigned to each resource block, for each resource block assigned in step S1703. Then, a modulation parameter is selected (S1704).

The scheduling unit 1514 transmits the transmission data to be transmitted to each terminal device 300 that has next notified the DCT2 reception state information, based on the value indicating the reception state generated in step S1702 in each channel of each terminal device 300. A value representing the reception state generated in step S1702 of each terminal device 300 allocated to each resource block for each resource block allocated in step S1705, allocated to the remaining resource blocks allocated in step S1703. Based on the above, a modulation parameter is selected (S1706). The scheduling unit 1514 transmits the transmission data to be transmitted to each terminal device 300 that has next notified the DCT3 reception state information, based on the value representing the reception state generated in step S1702 in each channel of each terminal device 300. A value representing the reception state generated in step S1702 of each terminal device 300 assigned to each resource block for each resource block assigned in step S1707, assigned to the remaining resource blocks assigned in step S1706. Based on the above, a modulation parameter is selected (S1708). The scheduling unit 1514 outputs a scheduling result (scheduling information) and a modulation parameter selection result (modulation parameter information), which are allocation results to the resource block (S1709).
Note that, for example, a scheduling operation and a modulation parameter selection operation in which the order of the terminal device 300 to be processed does not depend on the type of reception state information may be applied to the scheduling operation and the modulation parameter selection operation.

Next, details of the irreversible compression methods 1 to 3 including the discrete cosine transform DCT process and performed by the reception state information generation unit 309 will be described. The lossy compression method 1 and the lossy compression method 2 are the same lossy compression methods as the lossy compression methods shown in FIGS. 4 and 5 described in the first embodiment, respectively. A case where the lossy compression method shown in FIG. 18 is used as the compression method 3 will be described.
Similarly to FIGS. 4 and 5, FIG. 18 also shows the sample values after the discrete cosine transform DCT processing showing the result (signal component) of the reception state measurement result obtained by performing the discrete cosine transform DCT processing in correspondence with the sample number. ing. In the examples shown in FIGS. 4, 5, and 18, the lossy compression method 1, the lossy compression method 2, and the lossy compression method 3 are all the cases where the sample values at the sample points in the low frequency region are calculated. It is a lossless compression method. The lossy compression method 1 calculates a sample value at 32 sample points from the low frequency region side, the lossy compression method 2 calculates a sample value at 16 sample points from the low frequency region side, and the lossy compression method 3 calculates a low frequency. Sample values at 8 sample points are calculated from the region side. That is, the information amount of the reception state information output from the reception state information generation unit 309 is the largest when the notification request information is information requesting DCT1 reception state information, and the notification request information requests the DCT3 reception state information. Information is the smallest.

  Next, the reception state information compressed using the lossy compression method 1, the reception state information compressed using the lossy compression method 2, and the reception state information compressed using the lossy compression method 3, respectively. 6, FIG. 7, and FIG. 19 show values representing the reception state in each channel generated by the scheduling unit 1514. As can be seen from FIG. 6, the reception state G2 in each channel generated from the DCT1 reception state information, which is the reception state information compressed using the lossy compression method 1, is the same as the reception state measurement result G1 in each channel. I'm doing it. On the other hand, from FIG. 7, the reception state G4 in each channel generated from the DCT2 reception state information which is the reception state information compressed using the lossy compression method 2 is much less than the reception state measurement result G3 in each channel. It can be seen that only approximate variations in the channel direction are represented.

  Further, from FIG. 19, the reception state G6 in each channel generated from the DCT3 reception state information that is the reception state information compressed using the lossy compression method 3 is different from the reception state measurement result G5 in each channel. It can be seen that even when compared with the lossless compression method 2, there is no further coincidence, and only approximate fluctuations in the channel direction are represented. As described above, the lossy compression method 1 having the largest number of sample points for calculating the sample value has a large amount of information of the reception state information, and the reception state in each channel of the value indicating the reception state generated from the reception state information. It is characterized by high accuracy. Next, the accuracy of the reception state is the lossy compression method 2, and the lossy compression method 3 is the next, and the accuracy of the reception state decreases as the amount of reception state information decreases. .

  In the above description, the total number of channels is 64, and the sample points for calculating sample values in the lossy compression method 1, the lossy compression method 2 and the lossy compression method 3 are 32 and 16, respectively. Although an example of eight is given, it goes without saying that these parameters may be other numbers. For example, the total number of channels may be 100. In addition, the number of sample points for calculating the sample value may be one (if the number of sample points is 1, the sample value matches the average value of the reception state measurement results in all channels, so that the discrete cosine is calculated. Sample values can be calculated by averaging reception state measurement results instead of conversion DCT processing. When generating a value representing the reception state of each channel from reception state information, each reception state of each channel is calculated. The sample values may be calculated), and the sample values of all the sample points may be calculated. In short, the number of sample points in the lossy compression method 1 is larger than the number of sample points in the lossy compression method 2, and the number of sample points in the lossy compression method 2 is set larger than the number of sample points in the lossy compression method 3. It only has to be done.

  In addition, here, the lossy compression method 1, the lossy compression method 2, and the lossy compression method 3 are set so that the number of sample points is different, thereby making the information amount of the reception state information different. As described above, the reception state information generation unit 309 further compresses the sample values subjected to the discrete cosine transform DCT processing by quantizing them, and sets the quantization level number to be different, thereby differentiating the reception state information. It is also possible to vary the amount of information. For example, in each of the lossy compression method 1, the lossy compression method 2, and the lossy compression method 3, the number of sample points for calculating the sample value is set to 32, and the sample value at each sample point of the lossy compression method 1 is set. The sample value at each sample point of the lossy compression method 2 is represented by 4 bits, and the sample value at each sample point of the lossy compression method 3 is represented by 2 bits.

  As a result, as in the case where the number of sample points is set to be different, the lossy compression method 1 has the largest amount of reception state information and generates a value representing the reception state of each channel from the reception state information. It is possible to add the feature that the accuracy of the reception state is the highest. In this example, the lossy compression method 1, the lossy compression method 2, and the lossy compression method 3 all set the number of sample points to 32, and the lossy compression method 1 sample value is 8 bits, lossy compression. Although the case where the sample value of the method 2 is represented by 4 bits and the sample value of the lossy compression method 3 is represented by 2 bits has been described, it goes without saying that these parameters may be other numbers. It is sufficient that the number of quantization levels in the lossy compression method 1 is the largest, and conversely, the number of quantization levels in the lossy compression method 3 is set to be the smallest.

Furthermore, as a combination of these, the number of sample points and the number of quantization levels can be set differently in the lossy compression method 1, the lossy compression method 2, and the lossy compression method 3. Further, in the lossy compression methods 1, 2, and 3, it has been described that the quantization is performed after the discrete cosine transform DCT process is performed, but the discrete cosine transform DCT process may be performed after the quantization. In the lossy compression methods 1, 2, and 3, quantization may be performed without performing the discrete cosine transform DCT process. Further, in each irreversible compression method, the number of quantization levels may be set differently depending on the sample points. The lossy compression method 1 has a larger amount of reception state information (lower compression ratio) than the lossy compression method 2, and the lossy compression method 2 has a greater amount of information than the lossy compression method 3. In addition, each lossy compression method can be set so that the accuracy of the value representing the reception state of each channel generated by the scheduling unit 1514 of the base station apparatus 1500 is high.
In the above description, the case of selecting one irreversible compression method from among the three types of irreversible compression methods has been described. However, one irreversible compression method is selected from among the three types of irreversible compression methods. Of course, the present invention can be applied in the same manner.

  Thus, according to the present embodiment, when the reception state information is notified from the plurality of terminal apparatuses 300 to the base station apparatus 1500, the compression rate is low according to the downlink transmission data amount addressed to each terminal apparatus 300. DCT1 reception state information in which values representing the reception states of all channels are compressed by the lossy compression method 1 (with a large number of sample points) is reported, or the compression rate is higher than the lossy compression method 1 (the number of sample points is small) ) DCT2 reception state information in which values representing the reception states of all channels are compressed by the irreversible compression method 2 or an irreversible compression method having a higher compression rate (less sample points) than the irreversible compression method 2 3 is used to select whether to notify DCT3 reception state information in which values representing the reception states of all channels are compressed. Therefore, for a terminal device that needs to allocate many resource blocks in the downlink and transmit a large amount of transmission data, the scheduling unit 1514 of the base station device 1500 has a large number of sample points (since the compression rate is high). A value representing the detailed reception status of each channel can be obtained, and efficient scheduling and adaptive modulation based on the value representing the detailed reception status of each channel can be preferentially performed, so that higher-speed transmission can be achieved. realizable.

On the other hand, for the terminal devices 300 with relatively few data to be transmitted in the downlink, the notification of the DCT3 reception state information with the smallest number of sample points (high compression ratio) is selected. It is possible to reduce the amount of reception state information to be notified using.
As described above, the entire system realizes efficient reception state information notification by suppressing the total amount of uplink reception state information notification from each terminal device 300 and requires high-speed and large-capacity communication. By applying efficient scheduling and adaptive modulation to the terminal device 300, the efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system can be realized.

[Fifth Embodiment]
In the second embodiment, one irreversible compression method is selected from two types of irreversible compression methods based on the amount of downlink transmission data addressed to each terminal device and the delay dispersion of the propagation path in each terminal device. However, it is not always necessary to select two types, and one lossy compression method may be selected from two or more types of lossy compression methods. In the present embodiment, three irreversible compression methods are used when each terminal device 300 reports a reception state based on the amount of downlink transmission data addressed to each terminal device 300 and the delay dispersion of the propagation path in each terminal device 300. Decide from two lossy compression methods. Similarly, in the third embodiment, one irreversible compression method is selected from two types of irreversible compression methods based on the amount of downlink transmission data addressed to each terminal device and the maximum Doppler frequency in each terminal device. However, it is not always necessary to select two types, and one lossy compression method may be selected from two or more types of lossy compression methods.

  FIG. 20 is a schematic block diagram showing the configuration of the base station apparatus 2000 in the present embodiment. In addition, the terminal device in this embodiment is realizable with the structure similar to the structure of the terminal device 300 in 1st Embodiment. In the second embodiment, when a notification request is sent from the base station apparatus 1100 to each terminal apparatus 300, reception status information (DCT1) obtained by compressing the reception statuses of all channels by the lossy compression method 1 for each terminal apparatus 300. The case has been described in which one of the reception state information) and the reception state information (DCT2 reception state information) obtained by compressing the reception state of all channels by the lossy compression method 2 is selected based on the transmission data amount and the delay dispersion. In this embodiment, when a notification request is sent from the base station apparatus 2000 to each terminal apparatus 300, reception status information (DCT1 reception status information) obtained by compressing the reception statuses of all channels by the lossy compression method 1 for each terminal apparatus. ), Reception state information (DCT2 reception state information) obtained by compressing the reception state of all channels using the lossy compression method 2, and reception state information (DCT3 reception state information) obtained by compressing the reception state of all channels using the lossy compression method 3. ) Is selected based on the transmission data amount and the delay dispersion. In the present embodiment, the irreversible compression methods 1 to 3 use the same irreversible compression methods as the irreversible compression methods 1 to 3 described in the fourth embodiment.

  The base station device 2000 in the present embodiment includes a notification request determining unit 2013 corresponding to the notification request determining unit 913 of the base station device 900 and a scheduling unit 1514 corresponding to the scheduling unit 214 among the functional blocks. Different from the embodiment. The other configurations of the base station device 2000 and the terminal device 300 are the same as those in the second embodiment (FIGS. 11 and 3), and the scheduling unit 1514 is the same as the scheduling unit 1514 in the fourth embodiment. Description is omitted.

  The notification request determination unit 2013 in the base station device 2000 determines each terminal based on the delay dispersion measurement result measured by the delay dispersion measurement unit 1118 and the transmission data amount information addressed to each terminal device 300 from the transmission buffer unit 201. For the device 300, reception state information (DCT1 reception state information) obtained by compressing the reception state of all channels by the lossy compression method 1, and reception state information (DCT2) obtained by compressing the reception state of all channels by the lossy compression method 2. It is determined which of the three types of reception state information, that is, reception state information) and reception state information (DCT3 reception state information) obtained by compressing the reception state of all channels by the lossy compression method 3. Although the delay dispersion measuring unit 1118 has been described as being included in the base station apparatus 2000, the terminal apparatus 300 is provided, measures delay dispersion using a pilot signal of a downlink signal, and transmits the delay dispersion measurement result to the base station apparatus. You may make it report to 2000.

  Details of the notification request information determination operation in the notification request determination unit 2013 will be described with reference to FIG. FIG. 21 is a flowchart illustrating an example of the operation of determining notification request information in the present embodiment. First, the notification request determination unit 2013 acquires the transmission data amount addressed to each terminal apparatus 300 from the transmission buffer unit 201 (S2101), and the propagation path between the base station apparatus 2000 and each terminal apparatus 300 from the delay dispersion measurement unit 1118. The delay dispersion measurement result is acquired (S2102), and the following processing is repeated for each terminal device 300 (first to Nth terminal devices 300) (loop from S2103 to S2109).

  The notification request determination unit 2013 compares the transmission data amount addressed to the terminal device 300 with a predetermined first threshold value for each terminal device 300 (S2104), and if the transmission data amount is equal to or greater than the predetermined first threshold value. Further, the delay dispersion measurement result addressed to the terminal apparatus 300 is compared with a predetermined second threshold value (S2105). If the delay dispersion measurement result is equal to or greater than the predetermined second threshold value, the terminal apparatus 300 receives DCT1. Requesting status information is selected (S2106). In addition, the notification request determination unit 2013 determines that the transmission data amount is equal to or larger than a predetermined first threshold value in the comparison in step S2104 and the delay dispersion measurement result is smaller than the predetermined second threshold value in the comparison in step S2105. The terminal apparatus 300 is selected to request DCT2 reception status information (S2107). In addition, when the transmission data amount is less than the predetermined first threshold value in the comparison in step S2104, the notification request determination unit 2013 selects to request DCT3 reception state information from the terminal device 300 (S2108). .

The predetermined first threshold value is determined in advance by the average value of the amount of transmission data addressed to all the terminal devices 300, the number of terminal devices that notify DCT3 reception status information, and the number of terminal devices that notify other reception status information. A value that is set to be a ratio, a value that realizes a ratio of the number of terminal devices such that the total amount of reception status information notified from all terminal devices 300 according to notification request information is equal to or less than a predetermined value However, the present invention is not limited to this, and any value that is greater than 0 and equal to or less than the maximum transmission data amount per terminal device 300 that can be stored in the transmission buffer unit may be used.
In addition, the predetermined second threshold value is a value obtained by generating the reception state of each channel from the reception state information compressed by the irreversible compression method 2 and the generated reception state in each channel and the original reception state measurement result. Although it is preferable to use a value determined so that the difference is equal to or less than a predetermined value, the present invention is not limited to this, and a value representing the reception state of each channel is generated from the reception state information compressed by the lossy compression method 1. The difference between the generated reception state of each channel and the original reception state measurement result is generated when a value representing the reception state of each channel is generated from the reception state information compressed by the lossy compression method 2. Any delay dispersion value may be used as long as the difference between the reception state in each channel and the original reception state measurement result is approximately the same.

In the above description, the base station apparatus 2000 is used as an index indicating the difference between the reception state in each channel generated from the reception state information and the original reception state measurement result, or as an index indicating the frequency fluctuation of the reception state. Although the case where the delay dispersion of the propagation path with the terminal device 300 is used has been described, the present invention is not limited to this. For example, the coherent bandwidth of the propagation path between the base station device 2000 and the terminal device 300, the maximum sample number where the sample value is equal to or less than a predetermined value, the sample value of the predetermined sample number, and a predetermined value set in advance Other indices related to the accuracy of the reception state in each channel generated by the scheduling unit 1514 of the base station apparatus 2000, such as the difference between the two, may be used.
Furthermore, in the above description, the case where one irreversible compression method is selected from the three types of irreversible compression methods has been described. However, one irreversible compression method from among more than three types of irreversible compression methods. May be selected.

  As described above, according to the present embodiment, when the reception state information is notified from the plurality of terminal apparatuses 300 to the base station apparatus 1700, the downlink transmission data amount addressed to each terminal apparatus 300, each terminal apparatus 300, and the base station Whether to notify the DCT1 reception state information obtained by compressing the reception state of all channels using the lossy compression method 1 having a large number of sample points for calculating the sample value according to the delay dispersion of the propagation path with the device 2000 Select whether to notify DCT2 reception state information in which the reception state of all channels is compressed using the lossy compression method 2 having a smaller number of sample points than the lossy compression method 1, that is, a high compression rate, or lossy compression. DCT3 reception state information indicating reception states of all channels using the lossy compression method 3 having a smaller number of sample points than that of the method 2, that is, a high compression ratio. Choose whether to knowledge. Therefore, for a terminal device 300 that needs to allocate many resource blocks in the downlink and transmit a large amount of transmission data, since the number of sample points is large, a detailed reception state of each channel can be obtained. Efficient scheduling and adaptive modulation based on detailed reception conditions can be preferentially performed, and higher-speed transmission can be realized. Furthermore, even if it is necessary to transmit a large amount of transmission data, the number of sample points is relatively reduced for the terminal device 300 that can obtain a detailed reception state with a small number of sample points with small frequency fluctuations in the reception state. Therefore, it is possible to reduce the amount of reception state information notified from the terminal apparatus 300 using the uplink.

On the other hand, since the number of sample points is small for the terminal device 300 with relatively little data to be transmitted on the downlink, the amount of reception state information to be notified from the terminal device 300 using the uplink is reduced. Can do.
As described above, the entire system realizes efficient reception state information notification by suppressing the total amount of uplink reception state information notification from each terminal device 300 and requires high-speed and large-capacity communication. By applying efficient scheduling and adaptive modulation to the terminal device 300, the efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system can be realized.

[Sixth Embodiment]
FIG. 22 is a schematic block diagram showing the configuration of the base station device 2200 in the present embodiment. In each of the embodiments described above, a case is described in which the amount of transmission data addressed to each terminal device stored in the transmission buffer unit 201 is used as a reference for determining reception state information to be notified from the base station device to each terminal device. did. The base station apparatus 2200 according to the present embodiment uses the amount of time variation (hereinafter referred to as transmission data) of the transmission data amount addressed to each terminal apparatus 300 accumulated in the transmission buffer unit 2201 as a reference for determining the reception state information to be notified. The instantaneous bit rate) or the average amount thereof (hereinafter referred to as the average bit rate of transmission data) is used.

  Therefore, among the functional blocks of the base station device 2200, a transmission buffer unit 2201 corresponding to the transmission buffer unit 201 of the base station device 200 and a notification request determination unit 2213 corresponding to the notification request determination unit 213 of the base station device 200 are included. This is different from the first embodiment. Other configurations of the base station device 2200 and the configuration of the terminal device 300 are the same as those in the first embodiment (FIGS. 2 and 3), and a description thereof will be omitted. Note that, here, the first embodiment will be described in the case where the reference for determining the reception status information to be notified is changed from the data amount of the transmission data to the instantaneous bit rate or the average bit rate of the transmission data. Similarly, the second to fifth embodiments may be changed to the instantaneous bit rate or the average bit rate.

In FIG. 22, the transmission buffer unit 2201 accumulates input transmission data in a buffer for each terminal device 300 that is a transmission destination, and newly stores the transmission data in a transmission buffer within a predetermined time, for example, within the time of one subframe in FIG. An amount of transmission data addressed to each added terminal device 300, that is, an instantaneous bit rate of transmission data, or an average bit rate of transmission data that is an average value over a predetermined time of the transmission data instantaneous bit rate, for example, a predetermined number of subframes is calculated. And output to the notification request determination unit 2213.
The bit rate of transmission data addressed to each terminal device 300 is the quality of service (Quality) associated with the transmission data in an upper layer such as a network control layer or a medium access control layer (Media Access Control layer: MAC layer). of service (QoS) information may be used. In this case, QoS information regarding each transmission data is input to the transmission buffer unit 2201 from an upper layer, and based on this QoS information, the bit rate of the transmission data addressed to each terminal device 300 is calculated and output to the notification request determination unit 2213. .

  The notification request determination unit 2213 applies the lossy compression method 1 to each terminal device 300 based on the instantaneous bit rate of transmission data addressed to each terminal device 300 from the transmission buffer unit 2201 or the average bit rate of transmission data. Which of reception state information (DCT1 reception state information) indicating the reception state of all compressed channels and reception state information (DCT2 reception state information) indicating the reception state of all channels compressed by the lossy compression method 2 is used. Whether to make a notification request is determined, and the determination result is output to the downlink control information generation unit 215 as notification request information. In the present embodiment, the lossy compression method 1 and the lossy compression method 2 use the same lossy compression method as in the first embodiment.

  Next, details of the notification request information determination operation in the notification request determination unit 2213 will be described with reference to FIG. FIG. 23 is a flowchart illustrating an example of the operation for determining the notification request information in the present embodiment. First, the notification request determination unit 2213 acquires the instantaneous bit rate or average bit rate of transmission data addressed to each terminal device from the transmission buffer unit 221 (S2301), and each terminal device 300 (first to Nth terminal devices 300). ) Is repeated (the loop from S2302 to S2306).

  The notification request determination unit 2213 compares the instantaneous bit rate or average bit rate of transmission data addressed to the terminal device 300 with a predetermined threshold for each terminal device 300 (S2303), and the instantaneous bit rate or average of transmission data. When the bit rate is equal to or higher than the predetermined threshold, the terminal apparatus 300 is selected to request DCT1 reception state information (S2304). In addition, when the instantaneous bit rate or the average bit rate of the transmission data is less than a predetermined threshold in the comparison in step S2303, the notification request determination unit 2213 requests the terminal device 300 for DCT2 reception state information. Select (S2305).

  The predetermined threshold is determined in advance by the instantaneous bit rate or average bit rate of transmission data, the average value of all terminal devices 300, the number of terminal devices that notify DCT1 reception state information, and the number of terminal devices that notify DCT2 reception state information. A value that realizes the ratio of the number of terminal devices such that the total information amount of the reception status information notified from all the terminal devices according to the notification request information is less than or equal to a predetermined value. However, the present invention is not limited to this, and any value that is greater than 0 and equal to or less than the maximum communication speed (bit rate) per terminal device 300 in the downlink may be used.

  Thus, according to the present embodiment, when notifying the reception state information from the plurality of terminal apparatuses 300 to the base station apparatus 2000, the instantaneous bit rate or average bit rate of the downlink transmission data addressed to each terminal apparatus 300 is set. Correspondingly, DCT1 reception state information in which the reception states of all channels are compressed by the lossy compression method 1 with a large number of sample points for calculating sample values is notified or the lossy compression method with a small number of sample points for calculating sample values 2 is used to select whether to notify DCT2 reception state information in which the reception states of all channels are compressed. Therefore, for the terminal device 300 that needs to allocate many resource blocks in the downlink and transmit a large amount of transmission data per unit time, the detailed reception state of each channel can be obtained because the number of sample points is large. Thus, it is possible to preferentially perform efficient scheduling and adaptive modulation based on the detailed reception state of each channel, and higher speed transmission can be realized.

On the other hand, since the number of sample points is small for the terminal device 300 to which the data to be transmitted per unit time in the downlink is relatively small, the information amount of the reception state information to be notified from the terminal device 300 using the uplink Can be reduced.
As described above, the entire system realizes efficient reception state information notification by suppressing the total amount of uplink reception state information notification from each terminal device 300 and requires high-speed and large-capacity communication. By applying efficient scheduling and adaptive modulation to the terminal device 300, the efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system can be realized.

[Seventh Embodiment]
In each of the above embodiments, an OFDM system is assumed, and the channel is described as meaning one or a plurality of subcarriers. In the present embodiment, an example of an application method in a MIMO (Multiple Input Multiple Output) -OFDM system will be described in the case where one or a plurality of subcarriers of each transmission antenna is used as a channel.
FIG. 24 is a diagram illustrating an example of a downlink subframe configuration in the present embodiment. The base station apparatus transmits different signals from L (L is an integer of 2 or more) transmission antennas. The subframe includes L areas transmitted from each of the transmission antennas A1 to AL, and each area is further divided into K areas (K is a natural number) in the frequency direction. These L × K regions are referred to as channels Ch1-1 to ChK-L, respectively. This subframe means a transmission unit, and this subframe is a range in which a channel is allocated in one scheduling process. Further, the subframe is divided into T pieces (T is a natural number) with a predetermined time length TTI (Transmission Time Interval) in the time axis direction, and one TTI in one channel is set as a unit of scheduling (resource block).

Even in the MIMO-OFDM system having such a subframe configuration, the same processing as that in each of the above embodiments can be applied only in the area indicated by the term “channel” or “resource block”.
As described above, in a system that performs communication using a plurality of channels in a subframe, the present invention can be applied to a system in which the reception state of each channel in each terminal device may be different. Overall, it achieves efficient notification of reception status information by suppressing the total amount of uplink reception status information from each terminal device, and for terminal devices that require high-speed and large-capacity communication. Thus, efficient scheduling and adaptive modulation can be applied to achieve efficient scheduling and adaptive modulation that increase the transmission efficiency of the entire system.

[Eighth Embodiment]
In the present embodiment, the notification request determination unit 213 further has a high compression ratio for the terminal device 300 when the reception request information is first requested to the terminal device 300 in the first embodiment. That is, notification request information for requesting DCT2 reception state information in which the reception states of all channels are compressed by the irreversible compression method 2 with a small number of sample points for calculating sample values is generated. FIG. 25 is a diagram illustrating an example of a procedure related to notification of initial notification request information and reception state information between the base station device 200 and one certain terminal device 300 in the present embodiment. Although the case where the notification request is first made in the first embodiment will be described here, the present invention can be applied to the second to seventh embodiments in the same manner.

  Hereinafter, this embodiment will be described with reference to FIG. First, when the first downlink transmission data addressed to a certain terminal device 300 is input to the transmission buffer unit 201 (S2501), the base station device 200 requests notification request information for DCT2 reception state information from the terminal device 300. (S2502), and notifies the terminal apparatus 300 of the notification request information as part of the downlink control information (S2503). The terminal apparatus 300 receives notification request information requesting DCT2 reception state information, measures the reception state of each channel from downlink pilot symbols (S2504), and measures the reception state of all channels using the lossy compression method 2. DCT2 reception state information in which the result is compressed is generated (S2505) and notified to the base station apparatus 200 (S2506).

  Next, the base station apparatus 200 receives the DCT2 reception state information from the terminal apparatus 300, performs downlink scheduling and adaptive modulation together with the reception state information from the other terminal apparatuses 300 (S2507), Further, based on the amount of transmission data addressed to the terminal device 300, the reception status information requested to the terminal device 300 is selected from the DCT1 reception status information and the DCT2 reception status information to generate notification request information (S2508), and the notification request information To the terminal device 300 as a part of the downlink control information (S2509). FIG. 25 shows an example in which DCT1 reception state information is selected in step S2508, but DCT2 reception state information may also be selected.

  The terminal apparatus 300 receives notification request information requesting DCT1 reception state information, measures the reception state of each channel from downlink pilot symbols (S2510), and measures the reception state of all channels by the lossy compression method 1. DCT1 reception state information obtained by compressing the result is generated (S2511) and notified to the base station apparatus 200 (S25212). Thereafter, the procedure from step S2507 to step S2512 is repeated while transmission data addressed to the terminal device 300 exists. Note that steps S2502 to S2506 are procedures for notifying the first notification request information and the reception state information in this embodiment.

  In FIG. 25, the timing at which the first transmission data addressed to the target terminal device 300 is input to the transmission buffer unit 201 is described as the timing at which the reception status information is first requested. However, the timing is not limited to this. For example, the timing at which the target terminal device 300 makes a connection request to the base station device 200, the timing at which authentication is completed between the base station device 200 and the target terminal device 300, and the terminal device 300 temporarily interrupts communication It can also be applied to the timing of returning from a running state.

  Also, in this embodiment, the type of reception state information that the base station apparatus 200 first requests for notification has been described as DCT2 reception state information. However, as in the fourth and fifth embodiments, the reception state information When the type includes DCT3 reception status information, DCT3 reception status information may be requested.

  As described above, in the present embodiment, when the reception status information is first requested to the terminal device 300, the terminal device 300 has a small number of sample points for calculating the sample value, that is, the compression rate. DCT2 reception state information obtained by compressing the reception state of all channels by the high lossy compression method 2 is requested. As a result, when starting data communication between the base station apparatus 200 and the terminal apparatus 300, the number of sample points for calculating the sample value is small, that is, the compression rate is high, and therefore the uplink from the terminal apparatus 300 It is possible to reduce the amount of reception state information to be notified using.

In the first to eighth embodiments, the lossy compression method for compressing the reception state of all channels has been described. However, when channels that can be used in advance by the terminal device are limited, An irreversible compression method in which channels outside the restriction are not included in the compression target and reception state information may be used.
In the second embodiment, the irreversible compression method is determined based on the transmission data amount and the delay dispersion. In the third embodiment, the irreversible compression method is determined based on the transmission data amount and the maximum Doppler frequency. However, the lossy compression method may be selected based on the transmission data amount, the delay dispersion, and the maximum Doppler frequency.

  In addition, the transmission buffer unit 201, encoding unit 202, mapping unit 203, IFFT unit 204, GI insertion unit 205, demapping unit 211, decoding unit 212, notification request determination unit 213, scheduling unit 214, downlink in FIG. Control information generation unit 215, pilot generation unit 216, reception state information storage unit 217, or GI removal unit 304, FFT unit 305, demapping unit 306, decoding unit 307, reception state measurement unit 308, reception state in FIG. Information generation unit 309, encoding unit 310, mapping unit 311, demodulation control unit 314, or transmission buffer unit 201, encoding unit 202, mapping unit 203, IFFT unit 204, GI insertion unit 205, demapping unit in FIG. 1111, decryption unit 212, notification request determination unit 1113, schedule Ring unit 214, downlink control information generation unit 215, pilot generation unit 216, reception state information storage unit 217, delay dispersion measurement unit 1118, or transmission buffer unit 201, encoding unit 202, mapping unit 203, IFFT in FIG. Unit 204, GI insertion unit 205, demapping unit 1311, decoding unit 212, notification request determination unit 1313, scheduling unit 214, downlink control information generation unit 215, pilot generation unit 216, reception state information storage unit 217, fd measurement Unit 1319, or transmission buffer unit 201, encoding unit 202, mapping unit 203, IFFT unit 204, GI insertion unit 205, demapping unit 211, decoding unit 212, notification request determination unit 1513, scheduling unit 1514 in FIG. , Downlink control information generator 15, the pilot generation unit 216, the reception state information storage unit 217, or the transmission buffer unit 201, the encoding unit 202, the mapping unit 203, the IFFT unit 204, the GI insertion unit 205, the demapping unit 1111 and the decoding unit in FIG. 212, notification request determination unit 2013, scheduling unit 1514, downlink control information generation unit 215, pilot generation unit 216, reception state information storage unit 217, delay dispersion measurement unit 1118, or transmission buffer unit 2201 in FIG. Unit 202, mapping unit 203, IFFT unit 204, GI insertion unit 205, demapping unit 211, decoding unit 212, notification request determination unit 2213, scheduling unit 214, downlink control information generation unit 215, pilot generation unit 216, reception Function of state information storage unit 217 The program for realizing the above may be recorded on a computer-readable recording medium, and the program recorded on the recording medium may be read into a computer system and executed to execute the processing of each unit. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design and the like within a scope not departing from the gist of the present invention.

  The present invention is suitable for use in a mobile communication system that uses a plurality of channels in the downlink, but is not limited thereto.

It is the figure which showed an example of the sub-frame structure of the downlink in 1st Embodiment of this invention. It is a schematic block diagram which shows the structure of the base station apparatus 200 in the embodiment. It is a schematic block diagram which shows the structure of the terminal device 300 in the embodiment. It is a figure which shows an example of the sample value in each sample point at the time of using the lossy compression method 1 in the embodiment. It is a figure which shows an example of the sample value in each sample point at the time of using the lossy compression method 2 in the embodiment. It is a figure which shows the example of the receiving state in each channel which the scheduling part 214 produced | generated from the DCT1 receiving state information in the embodiment. It is a figure which shows the example of the receiving state in each channel which the scheduling part 214 produced | generated from the DCT2 receiving state information in the embodiment. It is a flowchart showing an example of the operation | movement of the notification request information determination in the embodiment. 4 is a flowchart illustrating an example of a scheduling operation and a modulation parameter selection operation in the same embodiment. 10 is a flowchart showing an example different from FIG. 9 of the scheduling operation and the modulation parameter selection operation in the embodiment. It is a schematic block diagram which shows the structure of the base station apparatus 1100 in 2nd Embodiment of this invention. It is a flowchart showing an example of the operation | movement of the notification request information determination in the embodiment. It is a schematic block diagram which shows the structure of the base station apparatus 1300 in 3rd Embodiment of this invention. It is a flowchart showing an example of the operation | movement of the notification request information determination in the embodiment. It is a schematic block diagram which shows the structure of the base station apparatus 1500 in 4th Embodiment of this invention. It is a flowchart showing an example of the operation | movement of the notification request information determination in the embodiment. 4 is a flowchart illustrating an example of a scheduling operation and a modulation parameter selection operation in the same embodiment. It is a figure which shows an example of the sample value in each sample point at the time of using the lossy compression method 3 in the embodiment. It is a figure which shows an example of the sample value in each sample point at the time of using the lossy compression method 3 in the embodiment. It is a schematic block diagram which shows the structure of the base station apparatus 2000 in 5th Embodiment of this invention. It is a flowchart showing an example of the operation | movement of the notification request information determination in the embodiment. It is a schematic block diagram which shows the structure of the base station apparatus 2200 in 6th Embodiment of this invention. It is a flowchart showing an example of the operation | movement of the notification request information determination in the embodiment. It is the figure which showed an example of the sub-frame structure of the downlink in 7th Embodiment of this invention. It is the figure which showed an example of the procedure relevant to the notification of the first notification request information and the receiving status information between the base station apparatus 200 and one certain terminal device 300 in 8th Embodiment of this invention. It is a figure which shows an example of a reception state measurement result. It is a figure which shows an example of the result of having carried out the discrete cosine transform DCT process on the reception state measurement result (FIG. 26).

Explanation of symbols

200, 1100, 1300, 1500, 2000, 2200 ... base station apparatus 201, 2201 ... transmission buffer unit 202 ... coding unit 203 ... mapping unit 204 ... IFFT unit 205 ... GI insertion unit 206 ... D / A conversion unit 207 ... wireless Transmission unit 208 ... Antenna unit 209 ... Wireless reception unit 210 ... A / D conversion unit 211, 1111, 1311 ... Demapping unit 212 ... Decoding unit 213, 1113, 1313, 1513, 2013, 2213 ... Notification request determination unit 214, 1514: Scheduling unit 215 ... Downlink control information generation unit 216 ... Pilot generation unit 217 ... Reception state information storage unit 300 ... Terminal device 301 ... Antenna unit 302 ... Radio reception unit 303 ... A / D conversion unit 304 ... GI removal unit 305 ... FFT unit 306 ... Demapping unit 307 ... Decoding unit 308 ... Reception state measurement unit 309 ... Reception state information generation unit 310 ... Encoding unit 311 ... Mapping unit 312 ... D / A conversion unit 313 ... Radio transmission unit 314 ... Demodulation control unit 1118 ... Delay dispersion measurement unit 1319 ... fd measurement unit

Claims (19)

Based on the reception status information received from the terminal device, in the base station device that allocates a channel used when transmitting transmission data to the terminal device,
Based on the bit rate for transmitting the transmission data to each of the terminal devices, one irreversible compression method is selected for each terminal device from a plurality of irreversible compression methods having different compression rates, and the reception state is represented. A request generating unit that generates notification request information representing a request for reception state information obtained by compressing information by the selected lossy compression method, for each terminal device;
A request transmission unit for transmitting the generated notification request information ,
The base station apparatus , wherein the request generation unit selects an irreversible compression method having a lower compression rate from the irreversible compression methods as the terminal device has a higher bit rate . Each of the lossy compression methods includes conversion by discrete cosine transform,
Wherein the lossy compression method, the discrete among sample values is a result of the cosine transform, the base station apparatus according to claim 1, sample points of sample values used for receiving status information are different from each other. Each of the irreversible compression methods includes transformation by quantization,
Wherein the lossy compression method, the base station apparatus according to claim 1, the number of quantization levels when performing the quantization are different from each other. Each of the lossy compression methods includes a discrete cosine transform and a transform by quantization,
The base station apparatus according to claim 3 , wherein the number of quantization levels when the sample value that is the result of the discrete cosine transform is quantized is different depending on the lossy compression method. The request generation unit selects one irreversible compression method for each terminal device based on a frequency variation index that is a value serving as an index of frequency variation in the reception state of the terminal device in addition to the bit rate. The base station apparatus according to any one of claims 1 to 4 , wherein: The request generation unit, the bit rate is large, and, according to claim 5, characterized in that the frequency variation represented by the frequency fluctuation index is larger terminal device, selects the low compression ratio lossy compression method Base station device. The base station apparatus according to claim 5 or 6 , wherein the frequency variation index is delay dispersion of a propagation path between each terminal apparatus and the base station apparatus. The request generation unit selects one irreversible compression method for each terminal device based on a time variation index that is a value serving as an index of time variation of the reception state of the terminal device in addition to the bit rate. The base station apparatus according to any one of claims 1 to 4 , wherein: The request generation unit, the bit rate is large, and, according to claim 8, characterized in that the time variation of the time fluctuation index is represented by the smaller terminal device, selects the low compression ratio lossy compression method Base station device. The base station apparatus according to claim 8 or 9 , wherein the time variation index is a maximum Doppler frequency of a propagation path between each terminal apparatus and the base station apparatus. The request generation unit, in addition to the bit rate , a time variation index that is a value that is an index of time variation of the reception state of the terminal device and a frequency that is a value that is an index of frequency variation of the reception state of the terminal device The base station apparatus according to any one of claims 1 to 4 , wherein one irreversible compression method is selected for each terminal apparatus based on a fluctuation index. The request generation unit uses an irreversible compression method with a lower compression rate for a terminal device having a higher bit rate, a larger frequency fluctuation represented by the frequency fluctuation index, and a smaller time fluctuation represented by the time fluctuation index. The base station apparatus according to claim 11 , wherein the base station apparatus is selected. The time variation index is a maximum Doppler frequency of a propagation path between each terminal device and the base station device,
The base station apparatus according to claim 11 or 12 , wherein the frequency variation index is delay dispersion of a propagation path between each terminal apparatus and the base station apparatus. The base station apparatus according to any one of claims 1 to 13 , wherein the request generation unit selects an irreversible compression method having the highest compression rate for the first time. A receiving unit that receives a signal including reception state information from each terminal device;
A scheduling unit that generates a reception state in each channel of each terminal device based on the reception state information and allocates a channel to the transmission data based on the reception state in each channel of the generated terminal device. The base station apparatus according to any one of claims 1 to 14 , wherein the base station apparatus is characterized in that The base station apparatus according to claim 15 , wherein the scheduling section allocates channels in order from transmission data addressed to a terminal apparatus for which an irreversible compression method with a low compression rate is selected. In a wireless communication system comprising: a terminal device that transmits reception state information; and a base station device that allocates a channel used when transmitting transmission data to the terminal device based on the received reception state.
The base station device
Based on the bit rate for transmitting the transmission data to each of the terminal devices, one irreversible compression method is selected for each terminal device from a plurality of irreversible compression methods having different compression rates, and the reception state is represented. A request generating unit that generates notification request information representing a request for reception state information obtained by compressing information by the selected lossy compression method, for each terminal device;
A request transmission unit for transmitting the generated notification request information,
The terminal device
A type acquisition unit for acquiring the notification request information from the received data;
A reception state information generation unit for generating reception state information requested by the acquired notification request information ,
The wireless communication system , wherein the request generation unit selects a lossy compression method having a lower compression rate from the lossy compression methods as the terminal device has a higher bit rate . In a reception state notification method in a wireless communication system comprising: a terminal device that transmits reception state information; and a base station device that allocates a channel used when transmitting transmission data to the terminal device based on the received reception state.
The base station apparatus selects one irreversible compression method for each terminal apparatus from a plurality of irreversible compression methods having different compression ratios based on a bit rate for transmitting the transmission data to each of the terminal apparatuses. And generating notification request information representing a request for reception state information obtained by compressing information indicating a reception state by the selected lossy compression method for each terminal device;
A second step in which the base station apparatus transmits the generated notification request information;
A third process in which the terminal device acquires the notification request information from received data;
A fourth process in which the terminal device generates reception state information requested by the acquired notification request information;
The terminal device has a fifth process of transmitting the generated reception state information to the base station device ;
In the first step, the terminal device with a higher bit rate selects an irreversible compression method with a lower compression rate from the irreversible compression methods. Based on the reception status information received from the terminal device, a computer provided in the base station device that allocates a channel used when transmitting transmission data to the terminal device,
Based on the bit rate for transmitting the transmission data to each of the terminal devices, one irreversible compression method is selected for each terminal device from a plurality of irreversible compression methods having different compression rates, and the reception state is represented. A request generation unit that generates notification request information for each of the terminal devices, which represents a request for reception state information obtained by compressing information by the selected lossy compression method;
Operate as a request transmitter that transmits the generated notification request information,
The request generation unit selects an irreversible compression method having a lower compression rate from the irreversible compression methods as the terminal device has a higher bit rate.
A program characterized by

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