Abstract:
Provided are a radio terminal device, a radio base station device, and a channel signal forming method which can prevent quality degradation of the downlink source allocation information by reducing the frequency of the zero information addition process to the downlink resource allocation information when executing communication using an uplink unit band and a plurality of downlink unit bands correlated to the uplink unit band. A base station ( 100 ) can execute communication using the uplink unit band and a plurality of downlink unit bands correlated to the uplink unit band. The base station ( 100 ) includes: a PDCCH generation unit ( 102 ) which includes the uplink allocation information relating to the uplink unit band only in some of the channel signals formed for each of the downlink unit bands; and a padding unit ( 103 ) which adds zero information to the downlink allocation information only in the selected some channel signals having the bandwidth of the corresponding downlink unit band smaller than that of the uplink unit band until the downlink allocation information size becomes equal to the uplink allocation information size.

Description:
TECHNICAL FIELD 
     The present invention relates to a radio terminal apparatus, a radio base station apparatus and a channel signal forming method. 
     BACKGROUND ART 
     With 3GPP LTE, OFDMA (Orthogonal Frequency Division Multiple Access) is adopted as a downlink communication scheme. In a radio communication system supporting 3GPP LTE, a base station transmits synchronizing signals (synchronization channels: SCHs) and broadcast signals (broadcast channels: BCHs) using predetermined communication resources. Then, a terminal first captures an SCH to secure synchronization with the base station. Then, the terminal acquires parameters (e.g. a frequency bandwidth and so forth) unique to the base station by reading BCH information (see Non-Patent Literatures 1 and 2). 
     After completing acquisition of the parameters unique to the base station, the terminal requests the base station for a connection to establish communication with the base station. The base station transmits control information to the terminal having established communication with the base station using PDCCHs (physical downlink control channels) if necessary. 
     Then, the terminal performs “blind detection” on a received PDCCH signal. That is, a PDCCH signal contains a CRC part, and, in the base station, this CRC part is masked with the terminal ID of the terminal to which the PDCCH signal should be transmitted. Therefore, the terminal cannot determine whether or not the PDCCH signal is directed to the terminal until demasking the CRC part of the received PDCCH signal with the terminal&#39;s ID. With this blind detection, when CRC calculation is OK as the result of demasking, this PDCCH signal is determined as a signal directed to the terminal. 
     In addition, control information transmitted from a base station includes resource allocation information containing information about resources allocated from the base station to a terminal. A terminal needs to receive both downlink resource allocation information and uplink resource allocation information. These downlink resource allocation information and uplink resource allocation information are transmitted using PDCCH signals having the same size. A. PDCCH signal contains the type information (e.g. one bit flag) about resource allocation information. Therefore, even if a PDCCH signal containing downlink resource allocation information and a PDCCH signal containing uplink resource allocation information have the same size, a terminal can distinguish between downlink resource allocation information and uplink resource allocation information by checking the type information about resource allocation information. Here, the format of PDCCHs used to transmit uplink resource allocation information is “PDCCH Format  0 ”, and the format of PDCCHs used to transmit downlink resource allocation information is “PDCCH Format  1 A.” 
     However, a ease is possible where the uplink bandwidth and the downlink bandwidth differ, and in this case, the size of information (that is, the number of bits required for transmission) is different between downlink resource allocation information and uplink resource allocation information. To be more specific, when the uplink bandwidth is small, the size of uplink resource allocation information is small, and, when the downlink bandwidth is small, the size of downlink resource allocation information is small. In this way, when the size of information varies due to a difference in bandwidth, zero information is added (that is, zero padding is performed) to either resource allocation information having a smaller size to make downlink resource allocation information and uplink resource allocation information have the same size. By this means, it is possible to keep the size of PDCCH signals the same regardless whether the information is downlink resource allocation information or uplink resource allocation information. 
     In addition, standardization of 3GPP LTE-Advanced that realizes communication faster than 3GPP LTE has been started. A 3GPP LTE-Advanced system (hereinafter, also referred to as “LTE-A system”) follows a 3GPP LTE system (hereinafter, also referred to as “LTE system”). With 3GPP LTE-Advanced, base stations and terminals that can perform communication in a wideband frequency equal to or higher than 20 MHz, will be introduced in order to realize a downlink transmission speed equal to or higher than maximum 1 Gbps. 
     Moreover, with 3GPP LTE-Advanced, a case is possible where the communication bandwidth of the uplink is not symmetrical to the communication bandwidth of the downlink, taking into account that there is a difference in the required throughput between the uplink and the downlink. To be more specific, with 3GPP LTE-Advanced, the communication bandwidth of the downlink may be wider than the communication bandwidth of the uplink. 
     Here, a base station supporting an LTE-A system (hereinafter, “LTE-A base station”) is configured to be able to perform communication using a plurality of “component bands.” “Component band” is a band having a width of the maximum 20 MHz, and is defined as the basic unit of communication bands. In addition, “component band” in the downlink (hereinafter referred to as “downlink component band”) may be defined as a band separated according to downlink frequency band information contained in a BCH broadcasted from a base station, or a band defined by the distribution width in which downlink control channels (PDCCHs) are distributed and assigned in the frequency domain. On the other hand, “component band” in the uplink (hereinafter “uplink component band”) may be defined as a band separated according to uplink frequency band information contained in a BCH broadcasted from a base station, or the basic unit of communication bands equal to or lower than 20 MHz including a PUSCH (physical uplink shared channel) around the center and including PUCCHs in both end parts. Here, in 3GPP LTE-Advanced, “component band (s)” may be written as “component carrier (s)” in English. 
       FIG. 1  shows an arrangement example of channels in an LTE-A system where the communication bandwidth (the number of component band s) for the uplink is not symmetrical to the communication bandwidth for the downlink. In  FIG. 1 , in order to make a terminal transmit an uplink signal, an LTE-A base station reports resource allocation information from both two downlink component bands, using PDCCHs. The uplink component band is associated with both downlink component bands, and therefore a PUSCH is transmitted using the same uplink component band even if uplink resource allocation information is transmitted using either downlink component band. In addition, downlink resource allocation information may be transmitted from both of two downlink component bands, and each downlink resource allocation information is used to indicate, to a terminal, a downlink-allocated resource in the downlink component band from which the resource allocation information is transmitted. 
     An LTE-A terminal can receive a plurality of component bands by receiving resource allocation information in this way. Here, an LTE terminal can receive only one component band at a time. In this way, bundling a plurality of component bands into an allocated band for a single communication is referred to as “carrier aggregation.” is possible to improve throughput using this carrier aggregation. 
     CITATION LIST 
     Non-Patent Literature 
     NPL 1 
     
         
         3GPP TS 36.211 V8.3.0, “Physical Channels and Modulation (Release 8),” May 2008
 
NPL 2
 
         3GPP TS 36.212 V8.3.0, “Multiplexing and channel coding (Release 8),” May 2008
 
NPL 3
 
         3GPP TS 36.213 V8.3.0, “Physical layer procedures (Release 8),” May 2008 
       
    
     SUMMARY OF INVENTION 
     Technical Problem 
     Here, in  FIG. 1 , the downlink communication bandwidth of an LTE-A system shown is 30 MHz, and includes two component bands including a downlink component band of 20 MHz in the low frequency side and a downlink component band of 10 MHz in the high frequency side. On the other hand, the uplink communication bandwidth is 20 MHz and includes one uplink component band. 
     In  FIG. 1 , the downlink component band in the low frequency side and the uplink component band have the same bandwidth, and therefore, with respect to this pair, uplink resource allocation information and downlink resource allocation information have the same size. Therefore, zero padding is not performed. By contrast with this, the downlink component band in the high frequency side and the uplink component band have different bandwidths, and therefore, with respect to this pair, zero information is added to the downlink resource allocation information having a smaller size until this downlink resource allocation information and the uplink resource allocation information have the same size. However, zero padding is performed for size adjustment, and zero information itself carries no meaning. That is, signals, which are actually unnecessary, are included in downlink control information, and therefore, when the power for the whole system is fixed, the power per information bit, which is actually necessary, decreases. 
     In addition, generally, the degree of importance of downlink control information is higher than that of uplink control information. It is because that downlink control information is used to report not only resource allocation information about downlink data channels, but also scheduling information about other important information (e.g. paging information and broadcast information). Therefore, it is desired to decrease the frequency of performing zero padding on downlink information. 
     Here, frequency diversity effect obtained using PDCCHs depends on the bandwidth of a downlink component band. Accordingly, the frequency diversity effect is small in a downlink component band having a narrow bandwidth, and therefore, it is desired to remove factors for quality deterioration as much as possible. However, when a downlink component band has a narrower bandwidth, the downlink component band is highly likely to be subject to zero padding. 
     This situation has not been impossible in an LTE system in which there is not concept of carrier aggregation, because the downlink frequency band is generally greater than the uplink frequency band in an LTE system. By contrast with this, in an LTE-A system in which carrier aggregation is introduced and a plurality of downlink component bands are associated with one uplink component band, even if the entire downlink frequency bandwidth is greater than the uplink frequency bandwidth, when each component band is focused on, a case is likely to frequently occur where a downlink component band is narrower than the uplink component band. 
     Moreover, in order to prevent zero padding, a case is possible where the size differs between uplink control information and downlink control information. However, in this case, the terminal side needs to perform blind detection separately on two pieces of control information having different numbers of information bits. Therefore, there is a problem of increase in the number of times of blind detections, and therefore the circuit scale increases. 
     It is therefore an object of the present invention to provide a radio terminal apparatus, a radio base station apparatus and a channel signal forming method that can prevent deterioration in the quality of downlink resource allocation information, by reducing the frequency of processing including adding zero information to downlink resource allocation information when performing communication using an uplink component band and a plurality of downlink component bands associated with the uplink component band. 
     Solution to Problem 
     The radio terminal apparatus according the present invention that can perform communication using an uplink component band and a plurality of downlink component bands associated with the uplink component band adopts a configuration to include: a radio receiving section that receives a control signal containing allocation information per downlink component band; and a control signal reception processing section that determines a basic information size used in reception processing on a control signal in each downlink component band and performs reception processing on the control signal based on the basic information size, wherein in a downlink component band containing uplink resource allocation information and downlink resource allocation information, the downlink component band being part of the plurality of downlink component bands, when an information size determined based on a bandwidth of a corresponding downlink component band is greater than an information size determined based on a bandwidth of the uplink component band, the basic information size is an information size determined based on the bandwidth of the downlink component band; when the information size determined based on the bandwidth of the corresponding downlink component band is smaller than the information size determined based on the bandwidth of the uplink component band, the basic information size is an information size determined based on the bandwidth of the uplink component band; and with respect to other downlink component bands, the basic information size is an information size determined based on the bandwidth of the downlink component band regardless of the bandwidth of the uplink component band. 
     The base station according to the present invention that can perform communication using an uplink component band and a plurality of downlink component bands associated with the uplink component band adopts a configuration to include: a forming section that forms a channel signal per downlink band; and a padding section that adds zero information to either downlink resource allocation information or uplink resource allocation information having a smaller size, in a channel signal containing both the downlink resource allocation information and the uplink resource allocation information until the downlink resource allocation information and the uplink resource allocation information have a same size, wherein the forming section includes both the uplink resource allocation information and the downlink resource allocation information in only part of the plurality of channel signals formed, and includes only the downlink resource allocation information in channel signals other than the part of the plurality of channel signals. 
     The channel signal forming method according to the present invention that forms channel signals containing downlink resource allocation information in an uplink component band and a plurality of downlink component band associated with the uplink component band, respectively, includes: putting uplink resource allocation information about the uplink component band in only part of the channel signals; and adding zero information to either downlink resource allocation information or uplink resource allocation information having a smaller size in a channel signal containing both the downlink resource allocation information and the uplink resource allocation information until the downlink resource allocation information and the uplink resource allocation information have a same size. 
     Advantageous Effects of Invention 
     According to the present invention, when communication is performed using an uplink component band and a plurality of downlink component bands associated with the uplink component band, the frequency of processing including adding zero information to downlink resource allocation information is reduced, and therefore, it is possible to provide a radio terminal apparatus, a radio base station apparatus and a channel signal forming method that can prevent deterioration in the quality of downlink resource allocation information. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  shows an arrangement example of channels in an LTE-A system in which the communication bandwidth (the number of component bands) of the uplink is not symmetrical to that of the downlink; 
         FIG. 2  is a block diagram showing a configuration of a base station according to Embodiment 1 of the present invention; 
         FIG. 3  is a block diagram showing a configuration of a terminal according to Embodiment 1 of the present invention; 
         FIG. 4  explains operation of a base station and operation of terminal; 
         FIG. 5  is a block diagram showing a configuration of a base station according to Embodiment 3 of the present invention; 
         FIG. 6  is a block diagram showing a configuration of a terminal according to Embodiment 3 of the present invention; 
         FIG. 7  shows a sequence when a base station and a terminal start carrier aggregation communication; 
         FIG. 8  is a conceptual diagram showing operation in a newly added downlink component band; 
         FIG. 9  is a conceptual diagram showing Operation in the basic component band set according to a command from a base station; and 
         FIG. 10  shows an arrangement example of channels in an LTE-A system in which the communication bandwidth (the number of component bands) of the uplink is not symmetrical to that of the downlink. 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     Now, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Here, the same components between embodiments are assigned the same reference numerals and overlapping descriptions will be omitted. 
     (Embodiment 1) 
       FIG. 2  is a block diagram showing the configuration of base station  100  according to Embodiment 1 of the present invention. In  FIG. 2 , base station  100  has control section  101 , PDCCH generating section  102 , padding section  103 , modulation sections  104  and  105 , SCH/BCH generating section  106 , multiplexing section  107 , IFFT section  108 , CP (cyclic prefix) adding section  109 , RF transmission section  110 , RF receiving section  111 , CP removing section  112 , FFT section  113 , extracting section  114 , IDFT section  115  and data receiving section  116 . Base station  100  is configured to be able to perform communication using an uplink component band and a plurality of downlink component bands associated with the uplink component band. 
     Control section  101  generates uplink resource allocation information and downlink resource allocation information for terminal  200  described later, outputs uplink resource allocation information to PDCCH generating section  102  and extracting section  114  and outputs downlink resource allocation information to PDCCH generating section  102  and multiplexing section  107 . 
     Control section  101  allocates downlink resource allocation information to all of a plurality of downlink component bands, and allocates uplink resource allocation information to only part of the plurality of downlink component bands. Here, among a plurality of downlink component bands associated with one uplink component band, uplink resource allocation information is allocated to, particularly, the downlink component band having the bandwidth which is the most similar to the bandwidth of the uplink component band. Hereinafter, a target downlink component band to which uplink resource allocation information is allocated, may also be referred to as “basic component band.” 
     Control section  101  outputs uplink resource allocation information and downlink resource allocation information to PDCCH generating section  102 , and also outputs information about an basic component band (hereinafter may also be referred to as “basic component band information”) to PDCCH generating section  102 . Here, SCH/BCH generating section  106  may include this basic component band information in a BCH. 
     In addition, control section  101  delivers bandwidth comparison information indicating size comparison between the bandwidth of an basic component band and the bandwidth of an uplink component band, to padding section  103  via PDCCH generating section  102 . 
     PDCCH generating section  102  generates a PDCCH signal to be transmitted in each downlink component band. In this case, PDCCH generating section  102  includes uplink resource allocation information and downlink resource allocation information in the PDCCH signal assigned to the downlink component band indicated by basic component band information, and includes only downlink resource allocation information in the PDCCH signal assigned to the other downlink component band. After that, the PDCCH signals are outputted to padding section  103 . 
     Padding section  103  adds zero information to either downlink resource allocation information or uplink resource allocation information having the smaller size until the downlink resource allocation information and the uplink resource allocation information have the same size in the inputted PDCCH signals. To which of downlink resource allocation information or uplink resource allocation information is added zero information, is determined based on bandwidth comparison information. 
     in addition, padding section  103  adds CRC bits to a PDCCH signal after padding processing and masks the CRC bits with the terminal ID. Then, padding section  103  outputs a PDCCH signal after masking, to modulation section  104 . 
     Modulation section  104  modulates the PDCCH signal inputted from PDCCH generating section  102 , and outputs a PDCCH signal after modulation to multiplexing section  107 . 
     Modulation section  105  modulates inputted transmission data (downlink data) and outputs a transmission data signal after modulation to multiplexing section  107 . 
     SCH/BCH section  106  generates an SCH and a BCH, and outputs the generated SCH and BCH to multiplexing section  107 . 
     Multiplexing section  107  multiplexes the PDCCH signal inputted from modulation section  104 , the data signal (i.e. PDSCH signal) inputted from modulation section  105 , and the SCH and BCH inputted from SCH/BCH generating section  106 . Here, multiplexing section  107  maps a data signal (PDSCH signal) to downlink component bands, based on downlink resource allocation information inputted from control section  101 . 
     IFFT section  108  transforms a multiplexed signal to time waveform, and CP adding section  109  adds a CP to this time waveform to generate an OFDM signal. 
     RF transmission section  110  applies transmission radio processing (up-conversion, digital-to-analog (D/A) conversion and so forth) to the OFDM signal inputted from CP adding section  109 , and transmits the result via an antenna. By this means, an OFDM signal containing resource allocation information is transmitted. 
     RF receiving section  111  applies reception radio processing (down-conversion, analog-to-digital (A/D) conversion and so forth), to a received radio signal received in a receiving band via an antenna, and outputs a resultant received signal to CP removing section  112 . 
     CP removing section  112  removes the CP from the received signal, and FFT section  113  transforms a received signal without a CP to a frequency domain signal. 
     Extracting section  114  extracts uplink data from the frequency domain signal inputted from FFT section  113 , based on uplink resource allocation information inputted from control section  101 . IDFT (inverse discrete Fourier transform) section  115  transforms an extracted signal to a time domain signal and outputs the time domain signal to data receiving section  116 . 
     Data receiving section  116  decodes the time domain signal inputted from IDFT section  115 . Then, data receiving section  116  outputs uplink data after decoding as received data. 
       FIG. 3  is a block diagram showing the configuration of terminal  200  according to Embodiment 1 of the present invention. In  FIG. 3 , terminal  200  has RF receiving section  201 , CP removing section  202 , FFT section  203 , frame synchronization section  204 , demultiplexing section  205 , broadcast signal receiving section  206 , PDCCH receiving section  207 , format determination section  208 , PDSCH receiving section  209 , modulation section  210 , DFT section  211 , frequency mapping section  212 , IFFT section  213 , CP adding section  214  and RF transmission section  215 . 
     RF receiving section  201  applies reception radio processing (down-conversion, analog-to-digital (A/D) conversion and so forth) to a received radio signal (here, OFDM signal) received in a receiving band via an antenna, and outputs a resultant received signal to CP removing section  202 . 
     CP removing section  202  removes the CP from the received signal, and FFT (fast Fourier transform) section  203  transforms a received signal without an CP to a frequency domain signal. This frequency domain signal is outputted to frame synchronization section  204 . 
     Frame synchronization section  204  searches for an SCH contained in the signal inputted from FFT section  203  and synchronizes with base station  100  (frame synchronization). In addition, frame synchronization section  204  obtains the cell ID associated with an SCH sequence. That is, frame synchronization section  204  performs the same processing as usual cell search. Then, frame synchronization section  204  outputs frame synchronization timing information indicating the frame synchronization timing and the signal inputted from FFT section  203 , to demultiplexing section  205 . 
     Demultiplexing section  205  demultiplexes the signal inputted from frame synchronization section  204  into a broadcast signal (i.e. BCH), a control signal (i.e. PDCCH signal) and a data signal (i.e. PDCCH signal), based on the frame synchronization timing information inputted from frame synchronization section  204 . Demultiplexing section  205  receives information about downlink component bands from broadcast signal receiving section  206 , and extracts a PDCCH signal for each of downlink component bands, based on this information. 
     Broadcast signal receiving section  206  reads the content of the BCH inputted from demultiplexing section  205 , and obtains information about the band (uplink and downlink bands) configuration of base station  100 . Broadcast signal receiving section  206  obtains, for example, the number of uplink component bands, the number of downlink component bands, the identification number and bandwidth of each component band, information about association between uplink and downlink component bands, basic component band information and so forth. Here, although it is possible to calculate an basic component band from the bandwidth of an uplink component band and the bandwidth of an downlink component band, base station  100  includes identification information about an basic component band in a BCH. Broadcast signal receiving section  206  outputs the obtained BCH information to format determination section  208  and PDCCH receiving section  207 . 
     PDCCH receiving section  207  performs blind detection on a PDCCH signal in each downlink component band, using the size of resource allocation information corresponding to the bandwidth of each downlink component band, the size of resource allocation information corresponding to the bandwidth of the uplink component band, and the terminal ID of terminal  200 . 
     That is, PDCCH receiving section  207  first determines a basic information size used to process each PDCCH signal, and specifies a part corresponding to CRC bits contained in each PDCCH signal, according to the determined basic information size. At this time, in base station  100 , the size of information may be adjusted using zero padding, as described above. Therefore, PDCCH receiving section  207  specifies a part corresponding to CRC bits in a PDCCH signal in an basic component band, using the size of basic information (payload size) determined based on either the bandwidth of the basic component band or the bandwidth of the uplink component band corresponding to the basic component band, whichever is wider. On the other hand, the downlink component band other than the basic component band includes only downlink resource allocation information. Therefore, PDCCH receiving section  207  specifies a part corresponding to CRC bits in the downlink component band other than the basic component band, using the basic information size matching the bandwidth of the downlink component band. 
     Next, PDCCH receiving section  207  demasks the specified part corresponding to CRC bits with the terminal  1 D of terminal  200 , and, if the result of CRC calculation for the entire PDCCH signal is OK, determines that this PDCCH signal is directed to terminal  200 . In this way, the PDCCH signal determined as a signal directed to terminal  200  is outputted to format determination section  208 . 
     Format determination section  208  determines whether the format of the PDCCH signal received from PDCCH receiving section  207 , is Format  0  or Format  1 A, based on the type information about the resource allocation information included in this PDCCH signal. When determining that the format is Format  0 , format determination section  208  outputs the uplink resource allocation information contained in the PDCCH signal to frequency mapping section  212 . In addition, when determining that the format is Format  1 A, format determination section  208  outputs the downlink resource allocation information contained in the PDCCH signal to PDSCH receiving section  209 . 
     PDSCH receiving section  209  extracts received data from the PDSCH signal inputted from demultiplexing section  205 , based on the downlink resource allocation information inputted from format determination section  208 . 
     Modulation section  210  modulates transmission data, and outputs a resultant modulated signal to DFT (discrete Fourier transform) section  211 . 
     DFT section  211  transforms the modulated signal inputted from modulation section  210 , and outputs a plurality of resultant frequency components to mapping section  212 . 
     Frequency mapping section  212  maps the plurality of frequency components inputted from DFT section  211  to a PUSCH assigned to the uplink component band. 
     IFFT section  213  transforms the plurality of mapped frequency components to a time domain waveform, and CP adding section  214  adds a CP to the time domain waveform. 
     RF transmission section  215  applies transmission radio processing (up-conversion, digital-to-analog (D/A) conversion and so forth) to a signal with the CP, and transmits the result via an antenna. 
     Next, operation of base station  100  and terminal  200  having the above-described configurations will be explained.  FIG. 4  explains operation of base station  100  and terminal  200 . 
     In  FIG. 4 , one uplink component band UB  1  is associated with three downlink component bands DBs  1  to  3 . Here, size comparison between the bandwidths of respective component bands as follows. Respective bandwidths of downlink component bands DBs  1  and  3  are wider than the bandwidth of uplink component band UB  1 . The bandwidth of downlink component band DB  2  is narrower than the bandwidth of uplink component band UB  1 . The bandwidth of downlink component band DB  1  is wider than the bandwidth of downlink component band DB  3 . The bandwidth of downlink component band DB  1  is similar to the bandwidth of uplink component band UB  3  more than the downlink component band DB  2 . That is, here, downlink component band DB  3  is the basic component band. 
     Base station  100  allocates uplink component band UB  1  to terminal  200  as an uplink resource, and allocates downlink component bands DBs  1  to  3  as downlink resources. 
     Then, base station  100  includes uplink resource allocation information and downlink resource allocation information in PDCCH signals and transmits the result to terminal  200 . 
     Here, base station  100  does not include uplink resource allocation information in all PDCCH signals, but includes uplink resource allocation information in only PDCCH signals assigned to part of downlink component bands. On the other hand, downlink resource allocation information is included in all PDCCH signals. 
     Particularly, with the present embodiment, the basic component band is a downlink component band having the bandwidth which is the most similar to the bandwidth of the uplink component band. Therefore, in  FIG. 4 , uplink resource allocation information is transmitted in only downlink component band DB  3 , which is the basic component band. Here, in  FIG. 4 , arrows from a PDCCH to uplink data (UL data) mean that uplink resource allocation information is transmitted using the PDCCH. In addition, arrows from each PDCCH to downlink data (DL data) or a D-BCH mean that downlink resource allocation information is transmitted using that PDCCH. 
     In addition, CRC bits are added to a PDCCH signal in padding section  103 . These CRC bits have been masked with the terminal ID assigned to terminal  200 . 
     In addition, adjustment of the size of information is performed on PDCCH signals if necessary. This adjustment of the size of information is performed on a PDCCH signal containing both uplink resource allocation information and downlink resource allocation information (that is, a PDCCH signal in the basic component band) in padding section  103 . To be more specific, padding section  103  adds zero information to either downlink resource allocation information or uplink resource allocation information having the smaller size until the downlink resource allocation information and the uplink resource allocation information have the same size. Here, in  FIG. 4 , the thickness of each arrow represents the size of the corresponding resource allocation information, where uplink resource allocation information and downlink resource allocation information have the same size in the basic component band. 
     Meanwhile, in terminal  200  that receives PDCCH signals, PDCCH receiving section  207  performs blind detection on PDCCH signals in respective downlink component bands, using the size of resource allocation information corresponding to the bandwidth of each downlink component band, the size of resource allocation information corresponding to the bandwidth of the uplink component band and the terminal ID of terminal  200 . 
     That is, PDCCH receiving section  207  first determines a basic information size used for processing each PDCCH, and specifies a part corresponding to CRC bits contained in a PDCCH signal according to the determined basic information size. To be more specific, in a PDCCH signal in downlink component band DB  3 , which is the basic component band, the a part corresponding to CRC bits specified using a basic information size (payload size) determined based on the wider one of the bandwidth of downlink component band DB  3  and the bandwidth of uplink component band UB  1  corresponding to downlink component band DB  3  (that is, the bandwidth of downlink component band DB  3 ). Meanwhile, PDCCH receiving section  207  specifies a part corresponding to CRC bits in each of the downlink component bands other than the basic component band, using the basic information size according to the bandwidth of each downlink component band. In this way, blind detection processing is switched between the basic component band and the downlink component bands other than the basic component band. 
     Next, PDCCH receiving section  207  demasks the specified part corresponding to CRC bits with the terminal ID of terminal  200 , and, if the result of CRC calculation for the entire PDCCH signal is OK, determines that this PDCCH signal is directed to terminal  200 . 
     Then, format determination section  208  determines whether the format of the PDCCH signal received from PDCCH receiving section  207 , is Format  0  or Format  1 A, based on the type information about the resource allocation information included in this PDCCH signal. 
     As described above, according to the present embodiment, PDCCH signals containing uplink resource allocation information are limited to the PDCCH signal assigned to part of downlink component bands, and therefore it is possible to reduce the rate of performing zero padding on downlink resource allocation information having a high degree of importance. Particularly, with the present embodiment, the basic component band is a downlink component band having the bandwidth which is the most similar to the bandwidth of the uplink component band, and therefore it is possible to limit a downlink component band in which zero padding is performed on downlink resource allocation information, to at most one band, that is, the basic component band. 
     In addition, only downlink resource allocation information is included in PDCCH signals in the downlink component bands other than the basic component band, so that the above-described adjustment of information size is not required. Therefore, it is possible to reduce the rate in which zero padding is performed on downlink resource allocation information. Likewise, it is possible to minimize the number of times of padding and the frequency to perform padding on uplink resource allocation information. 
     That is, it is possible to minimize the frequency of performing zero padding processing on both uplink resource allocation information and downlink resource allocation information, so that it is possible to improve the quality of both uplink resource allocation information and downlink resource allocation information and also improve system performance. 
     Moreover, according to the present embodiment, adjustment of the size of information is performed to make downlink resource allocation information and uplink resource allocation information have the same size in a PDCCH signal in the basic component band. 
     By this means, it is possible to match the position of a part corresponding to CRC bits in a PDCCH signal between downlink resource allocation information and uplink resource allocation information. Therefore, in the receiving side, it is possible to specify a part corresponding to CRC bits without distinguishing between downlink resource allocation information and uplink resource allocation information, based on the information size (payload size) determined based on the wider one of the bandwidth of the basic component band and the bandwidth of the uplink component band corresponding to the basic component band, or the information size determined based on the wider one of downlink resource allocation information determined by the bandwidth of the basic component band or uplink resource allocation information determined by the bandwidth of the uplink component band. That is, it is possible to apply the same blind detection processing to downlink resource allocation information and uplink resource allocation information, and therefore it is possible to prevent increase in the number of times of blind detections. 
     (Embodiment 2) 
     Even if an uplink component band and a downlink component band have the same bandwidth, a case is possible in which downlink resource allocation information and uplink resource allocation information have different sizes, and the present embodiment differs from Embodiment 1 only in that the case is focused. 
     That is, with Embodiment 1, a case has been explained in which downlink resource allocation information and uplink resource allocation information in a downlink component band as the basic component band, have the same size as long as an uplink component band and a downlink component band have the same bandwidth. By contrast with this, with the present embodiment, even if an uplink component band and a downlink component band have the same bandwidth, downlink resource allocation information and uplink resource allocation information have approximately the same size, but do not have exactly the same size. It is because, when an uplink component band and a downlink component band have the same size, the amount of information required to indicate resource positions is the same, but the amount of information required to report information about other controls differs between downlink resource allocation information and uplink resource allocation information. In addition, when a difference in the bandwidth between an uplink component band and a downlink component band is greater, a difference in the size between downlink resource allocation information and uplink resource allocation information increases. 
     Therefore, with the present embodiment, in order to make downlink resource allocation information and uplink resource allocation information have the same size, when downlink resource allocation information and uplink resource allocation information have different sizes, zero information is added to resource allocation information allocated to PDCCHs in part of downlink component bands (zero padding). 
     Now, the present embodiment will be described in detail. Here, the basic configurations of a base station and a terminal according to the present embodiment are the same as the configurations of a base station and a terminal described in Embodiment 1. Therefore, a base station and a terminal according to the present embodiment will be described with reference to  FIG. 2  and  FIG. 3 . 
     Control section  101  in base station  100  ( FIG. 2 ) according to the present embodiment delivers information size comparison information indicating size comparison between the size of downlink resource allocation information determined by the bandwidth of an basic component band and the size of uplink resource allocation information determined by the bandwidth of an uplink component band, to padding section  103  via PDCCH generating section  102 . 
     Padding section  103  adds zero information to either downlink resource allocation information or uplink resource allocation information having a smaller size until the downlink resource allocation information and uplink resource allocation information have the same size. To which of downlink resource allocation information and uplink resource allocation information is added zero information is determined based on information size comparison information. 
     Meanwhile, PDCCH receiving section  207  in terminal  200  ( FIG. 3 ) performs blind detection on a PDCCH signal in each downlink component band, using the size of resource allocation information corresponding to the bandwidth of each downlink component band, the size of resource allocation information corresponding to the bandwidth of an uplink component hand, and the terminal ID of terminal  200 . 
     That is, PDCCH receiving section  207  first determines a basic information size used for processing each PDCCH, and specifies a part corresponding to CRC bits contained in a PDCCH signal according to the determined basic information size. At this time, in base station  100 , adjustment of the size of information may be performed using zero padding as described above. Therefore, PDCCH receiving section  207  specifies a part corresponding to CRC bits in a PDCCH signal in a basic component band, using the greater one of the size of downlink resource allocation information determined based on the bandwidth of the basic component band and the size of uplink resource allocation information determined based on the bandwidth of the uplink component band corresponding to the basic component band, as a basic information size (payload size). On the other hand, the downlink component bands other than the basic component band contain only downlink resource allocation information. Therefore, PDCCH receiving section  207  specifies a part corresponding to CRC bits in each downlink component band other than the basic component band, using the basic information size determined based on the bandwidth of the downlink component band. 
     Next, operation of base station  100  and terminal  200  having the above described configurations will be described with reference to  FIG. 4  like in Embodiment 1. 
     In  FIG. 4 , one uplink component band UB  1  is associated with three downlink component bands DBs  1  to  3  like in Embodiment 1. Here, in  FIG. 4 , size comparison between respective bandwidths of component bands is as follows. Respective bandwidths of downlink component bands DBs  1  and  3  are wider than the bandwidth of uplink component band UB  1 . The bandwidth of downlink component band DB  2  is narrower than the bandwidth of uplink component band UB  1 . The bandwidth of downlink component band DB  1  is wider than the bandwidth of downlink component band DB  3 . The bandwidth of uplink component band UB  1  is similar to the bandwidth of the bandwidth of downlink component band DB  3  more than the bandwidth of downlink component band DB  2 . That is, here, downlink component band DB  3  is the basic component band. 
     Base station  100  allocates uplink component band UB  1  to terminal  200  as an uplink resource and allocates downlink component bands DBs  1  to  3  to terminal  200  as downlink resources. 
     Then, base station  100  includes uplink resource allocation information and downlink resource allocation information in. PDCCH signals and transmits these signals to terminal  200 . 
     Here, base station  100  does not include uplink resource allocation information in all PDCCH signals, but includes uplink resource allocation information in only PDCCH signals assigned to part of downlink component bands. On the other hand, downlink resource allocation information is included in all PDCCH signals. 
     Particularly, with the present embodiment, the basic component band is a downlink component band having the bandwidth which is the most similar to the bandwidth of the uplink component band. Therefore, in  FIG. 4 , uplink resource allocation information is transmitted in only downlink component band DB  3 , which is the basic component band. Here, in  FIG. 4 , arrows from a PDCCH to uplink data (UL data) mean that uplink resource allocation information is transmitted using the PDCCH. In addition, arrows from each PDCCH to downlink data (DL data) or a D-BCH mean that downlink resource allocation information is transmitted using the PDCCH. 
     In addition, CRC bits are added to each PDCCH signal in padding section  103 . These CRC bits are masked with the terminal ID assigned to terminal  200 . 
     In addition, adjustment of the size of information is performed on PDCCH signals if necessary. 
     This adjustment of the size of information is performed on a PDCCH signal containing both uplink resource allocation information and downlink resource allocation information (that is, a PDCCH signal in the basic component band) in padding section  103 . To be more specific, padding section  103  adds zero information to either downlink resource allocation information or uplink resource allocation information having a smaller size until the downlink resource allocation information and the uplink resource allocation information have the same size. Here, in  FIG. 4 , the thickness of each arrow represents the size of the corresponding resource allocation information, where uplink resource allocation information and downlink resource allocation information have the same size in the basic component band. 
     Meanwhile, in terminal  200  that receives PDCCH signals, PDCCH receiving section  207  performs blind detection on PDCCH signals in respective downlink component bands, using the size of resource allocation information corresponding to the bandwidth of each downlink component band, the size of resource allocation information corresponding to the bandwidth of the uplink component band and the terminal ID of terminal  200 . 
     That is, PDCCH receiving section  207  first determines a basic information size used for processing each PDCCH, and specifies a part corresponding to CRC bits contained in a PDCCH signal according to the determined basic information size. To be more specific, in a PDCCH signal in downlink component band DB  3 , which is the basic component band, a part corresponding to CRC bits, using the greater one of the size of downlink resource allocation information determined based on the bandwidth of downlink component band DB  3  and the size of uplink resource allocation information determined based on the bandwidth of uplink component band UB  1  corresponding to downlink component band DB  3 , as a basic information size (payload size). Meanwhile, PDCCH receiving section  207  specifies a part corresponding to CRC bits in each of the downlink component bands other than the basic component band, using the basic information size determined based on the bandwidth of each downlink component band. In this way, blind detection processing is switched between the basic component band and the downlink component bands other than the basic component band. 
     Next, PDCCH receiving section  207  demasks the specified part corresponding to CRC bits with the terminal ID of terminal  200 , and, if the result of CRC calculation for the entire PDCCH signal is OK, determines that this PDCCH signal is directed to terminal  200 . 
     Then, format determination section  208  determines whether the format of the PDCCH signal received from PDCCH receiving section  207 , is Format  0  or Format  1 A, based on the type information about the resource allocation information included in this PDCCH signal. 
     As described above, according to the present embodiment, PDCCH signals containing uplink resource allocation information are limited to the PDCCH signal assigned to part of downlink component bands like in Embodiment 1, and therefore it is possible to reduce the rate of performing zero padding on downlink resource allocation information having a high degree of importance. Particularly, with the present embodiment, the basic component band is a downlink component band having the bandwidth which is the most similar to the bandwidth of the uplink component band, and therefore it is possible to limit a downlink component band in which zero padding is performed on downlink resource allocation information, to at most one band, that is, the basic component band. 
     In addition, only downlink resource allocation information is included in PDCCH signals in the downlink component bands other than the basic component band, so that the above-described adjustment of information size is not required. Therefore, it is possible to reduce the rate of performing zero padding on downlink resource allocation information. Likewise, it is possible to minimize the number of times of performing padding and the frequency of performing padding on uplink resource allocation information. 
     That is, it is possible to minimize the frequency of performing zero padding processing on both uplink resource allocation information and downlink resource allocation information, so that it is possible to improve the quality of both uplink resource allocation information and downlink resource allocation information and also improve system performance. 
     (Embodiment 3) 
     The present embodiment differs from Embodiments 1 and 2 in that a base station variably sets a base component band for each terminal. 
     That is, in Embodiment 3, at the time a base station starts high-speed communication with a certain terminal using carrier aggregation, the basic component band is set according to the same criterion as in Embodiment 1 or 2. However, with Embodiment 3, a base station can command terminals to add and change the basic component band at any time. 
     Now, each component and the operation in base station  300  and terminal  400  according to Embodiment 3 of the present invention will be described in detail with reference to  FIG. 5  to  FIG. 9 . 
       FIG. 5  is a block diagram showing the configuration of base station  300  according to Embodiment 3 of the present invention. As compared to base station  100  shown in  FIG. 2 , base station  300  shown in  FIG. 5  has control section  301  instead of control section  101 , padding section  302  instead of padding section  103  and modulation section  305  instead of modulation section  105 . Here, in  FIG. 5 , the same components as in  FIG. 2  are assigned the same reference numerals and descriptions will be omitted. 
     Control section  301  in base station  300  according to the present embodiment holds basic component band information, which is set by base station  300 , for each terminal  400 . Here, a plurality of basic component bands may be set for one terminal  400 . 
     In addition, control section  301  delivers basic component band setting information set for each terminal  400 , and “information size comparison information” which represents size comparison between the size of downlink resource allocation information determined based on the bandwidth of each basic component band and the size of uplink resource allocation information determined based on the bandwidth of the uplink component band, to padding section  303  via PDCCH generating section  102 . 
     Moreover, when changing the basic component band setting information set for terminal  400 , in order to transmit the thing as data for terminal  400 , control section  301  outputs new “basic component band setting information” to modulation section  305 . 
     Padding section  303  adds zero information to either downlink resource allocation information or uplink resource allocation information having the smaller size until the downlink resource allocation information and the uplink resource allocation information have the same size. To which of downlink resource allocation information and uplink resource allocation information is added zero information is determined based on information size comparison information. Resource allocation information to which zero information is added is outputted to modulation section  104  if necessary. 
     When receiving the basic component band setting information for terminal  300 , modulation section  305  modulates that information as part of transmission data to terminal  300  and outputs the result to multiplexing section  107 . 
       FIG. 6  is a block diagram showing the configuration of terminal  400  according to Embodiment 3 of the present invention. As compared to terminal  200  according to Embodiment 1 shown in  FIG. 3 , terminal  400  shown in  FIG. 6  has PDCCH receiving section  407  instead of PDCCH receiving section  207  and has PDSCH receiving section  409  instead of PDSCH receiving section  209 . Here, in  FIG. 6 , the same components as in  FIG. 3  are assigned the same reference numerals and descriptions will be omitted. 
     PDCCH receiving section  407  in terminal  400  according to the present embodiment performs blind detection on PDCCH signals in respective downlink component bands, using the size of resource allocation information corresponding to the bandwidth of each downlink component band, the size of resource allocation information corresponding to the bandwidth of the uplink component band and the terminal ID of terminal  400 . 
     That is, PDCCH receiving section  407  first determines a basic information size used to process each PDCCH, and specifies a part corresponding to CRC bits contained in a PDCCH signal according to the determined basic information size. At this time, in base station  300 , adjustment of the size of information may be performed using zero padding as described above. Therefore, PDCCH receiving section  407  specifies a part corresponding to CRC bits in a PDCCH signal in each basic component band, using the greater one of the size of downlink resource allocation information determined based on the bandwidth of each basic component band and the size of uplink resource allocation information determined based on the bandwidth of the uplink component band corresponding to the basic component band, as a basic information size (payload size). On the other hand, the downlink component bands other than the basic component band contain only downlink resource allocation information. Therefore, PDCCH receiving section  407  specifies a part corresponding to CRC bits in each downlink component band other than the basic component band, using the basic information size determined based on the bandwidth of the downlink component band. 
     In addition, PDCCH receiving section  407  determines a plurality of basic component bands described above, according to basic component band setting information inputted from PDSCH receiving section  409 . 
     PDSCH receiving section  409  extracts received data from a PDSCH signal inputted from demultiplexing section  205 , based on downlink resource allocation information inputted from format determination section  208 . Here, when the received data contains information reporting change in the basic component band setting, PDSCH receiving section  409  outputs that information to PDCCH receiving section  407  as new basic component band setting information. 
     Next, operation of base station  300  and terminal  400  having the above-described configurations will be described using  FIG. 7  to  FIG. 9  as support. 
       FIG. 7  shows a sequence when base station  300  and terminal  400  start carrier aggregation communication. As shown in  FIG. 7 , base station  300  periodically transmits uplink component band information using a certain downlink component band (downlink component band  1  in  FIG. 7 ) (step  1 ). When successfully receiving the uplink component band information from base station  300 , terminal  400  requests to start communication with base station  300  using that uplink component band, and therefore starts communication with base station  300  (step  2 ). In this case, only one downlink component band and one uplink component band are set for terminal  400 , and therefore, this downlink component band (downlink component band  1  in  FIG. 7 ) is set for base station  300  and terminal  400  as the basic component band. 
     After communication between base station  300  and terminal  400  is established, when base station  300  sets aggregation communication with terminal  400 , depending on the situation of communication traffic, base station  300  reports that downlink component band  2  is used in communication with terminal  400 , to terminal  400  individually, so that carrier aggregation communication is set between base station  300  and terminal  400  (step  3 ). This individual report (dedicated signaling) to terminal  400  includes, for example, plurality of information elements including the frequency position and frequency bandwidth of a component band newly added (i.e. downlink component band  2 ), information indicating whether or not the component band newly added is set as the basic component band, and so forth. Here, at this time, only one uplink component band is set, and therefore two component bands used in carrier aggregation are both associated with that uplink component band. 
     Next,  FIG. 8  is a conceptual diagram showing operation in the above-described downlink component band newly added. In  FIG. 8 , the bandwidth of downlink component band  1  originally used in communication is 15 MHz, and the bandwidth of downlink component band  2  newly added is 10 MHz, where both bandwidths are smaller than the bandwidth (20 MHz) of uplink component band  1 . 
     As shown in  FIG. 7 , in the initial state in which terminal  400  starts communication with base station  300  (that is, before charier aggregation communication is set: step  2 ), only one downlink component band is set for terminal  400 , so that downlink component band  1  is the basic component band for terminal  400  regardless size comparison with the bandwidth of the uplink component band. 
     By contrast with this, when carrier aggregation communication is started between base station  300  and terminal  400  (step  3  in  FIG. 8 ), whether or not a downlink component band newly added is set as the basic component band is determined based on whether or not information elements contained in dedicated signaling from base station  300  include basic component band setting information. That is, a flow of adding a downlink component band is different from a flow of determining an added downlink component band as the basic component band. 
     To be more specific, if there is an information element containing basic component band setting information in dedicated signaling transmitted from base station  300  to terminal  400  at the time of starting carrier aggregation, a downlink component band newly added is set as the basic component band without any conditions. 
     On the other hand, if there is no information element containing basic element band setting information in the above-described dedicated signaling, whether or not a downlink component band newly added is the basic component band is determined in the terminal  400  side, based on “specified default configuration”). That is, in order to determine whether or not a component band newly added is set as the basic component band, terminal  400  compares between the size of downlink resource allocation information determined based on the bandwidth of the component band newly added (i.e. downlink component band  2 ) and the size of uplink resource allocation information determined based on the bandwidth of uplink component band  1 . Then, as the result of the comparison, when the size of the downlink resource allocation information is equal to or greater than the size of the uplink resource allocation information, terminal  400  sets the downlink component band newly added is the basic component band, and, on the other hand, when the size of the uplink resource allocation information is greater than the size of the downlink resource allocation information, does not set the downlink component band newly added, as the basic component band. In  FIG. 8 , the size of the uplink resource allocation information is greater, and therefore the downlink component band newly added is not set as the basic component band. 
     That is, base station  300  determines whether or not to transmit Format  0  from the newly downlink band to terminal  400  as default setting, based on the above-described comparison result. In addition, PDCCH receiving section  407  in terminal  400  determines the size of downlink resource allocation information, based on the above-described comparison result. 
     Here, even if the basic component band is set in the initial state in which carrier aggregation is started between base station  300  and terminal  400  as described above, after that, base station  300  reports an information element containing basic component band setting information to terminal  400  individually, depending on situations, and therefore can change whether or not downlink component band  2  is the basic component band for terminal  400 . Then, when downlink component band  2  is set as the basic component band, base station  300  matches the size of Format  1 A with the size of Format  0  in downlink component band  2 , by means of padding. 
     Moreover, when receiving a report that downlink component band  2  is the basic component band, from base station  300 , PDCCH receiving section  407  in terminal  400  determines the size of downlink resource allocation information assume that the size of Format  1 A is the same as the size of Format  0  in downlink component band  2  by padding. 
     As described above, according to the present embodiment, default setting of whether or not a downlink component band newly added at the time of starting carrier aggregation is set as the basic component band, is specified based on comparison between the size of downlink resource allocation information determined based on the bandwidth of the downlink component band newly added and the size of uplink resource allocation information determined based on the bandwidth of the uplink component band. Accordingly, it is possible to realize preferable operation for the performance of Format  1 A. Moreover, base station  300  optionally changes setting of the basic component band for each terminal  400 , depending on information of communication traffic. 
     That is, as default operation, only when the information size determined based on the bandwidth of a downlink component band newly added at the time of starting carrier aggregation is equal to or greater than the information size determined based on the bandwidth of the uplink component band associated with that downlink component band, control section  301  in base station  300  determines that downlink component band as the basic component band. In other words, when a communication component band is added to the initial communication component band, control section  301  sets, as default operation, only a downlink component band having a size greater than the information size determined based on the bandwidth of the uplink component band associated with that downlink component band, as the basic component band. By this means, it is possible to prevent padding on downlink resource allocation information in a downlink component band newly added, without signaling to the terminal. 
     (Another Embodiment) 
     (1) With Embodiments 1 and 2, downlink component bands satisfying the following conditions may be selected as the basic component band. That is, first, a downlink component band having a bandwidth equal to or greater than the bandwidth of the uplink component band may be selected as the basic component band. By this means, it is possible to eliminate zero padding due to the size comparison between the bandwidths with respect to downlink resource allocation information. In addition, secondly, a downlink component band having a bandwidth, which is equal to or more than the bandwidth of the uplink component band and which is the most similar to the bandwidth of the uplink component band, may be selected as the basic component band. By this means, also it is possible to eliminate zero padding due to the size comparison between the bandwidths. 
     (2) in addition, an LTE-A base station needs to support both LTE terminals and LTE-A terminals. As described above, however, an LTE terminal can perform communication in only one component band at a time. When communicating with base station  100 , an LTE terminal needs uplink resource allocation information and downlink resource allocation information, naturally. Therefore, an LTE terminal cannot be allocated to downlink component bands other than the basic component band, to which only downlink resource allocation information are transmitted, but can be allocated to only the basic component band. Therefore, when base station  100  according to Embodiments 1 and 2 is an LTE-A base station, the basic component band may be a band in which an LTE-A terminal and an LTE terminal can exist together. 
     An SCH and a P-BCH for at least an LTE terminal are transmitted in a band in which an LTE-A terminal and an LTE terminal can exist together in an LTE-A system, as shown in  FIG. 10 . These SCH and P-BCH for an LTE terminal are used by an LTE-A terminal. 
     Therefore, in an LTE-A system, terminal  200  according to Embodiments 1 and 2 can determine whether or not a certain downlink component band is the basic component band, based on whether or not the downlink component band can receive an SCH and a P-BCH for an LTE terminal as a criterion for determination. Based on the result of the determination, terminal  200  can switch blind detection processing between the basic component band and the other downlink component bands as described above. 
     In addition, in Embodiments 1 and 2, when information about a coexisting band is reported to terminals by broadcast information such as a BCH, the basic component band may be specified based on the information about the coexisting band. Moreover, information about a coexisting band is not limited to broadcast information, and may be reported to each terminal using a dedicated channel. 
     (3) Also, although cases have been described with the above embodiment as examples where the present invention is configured by hardware, the present invention can also be realized by software. 
     Each function block employed in the description of each of the aforementioned embodiments may typically be implemented as an LSI constituted by an integrated circuit. These may be individual chips or partially or totally contained on a single chip. “LSI” is adopted here but this may also be referred to as “IC,” “system LSI,” “super LSI,” or “ultra LSI” depending on differing extents of integration. 
     Further, the method of circuit integration is not limited to LSI&#39;s and implementation using dedicated circuitry or general purpose processors is also possible. After LSI manufacture, utilization of a programmable FPGA (Field Programmable Gate Array) or a reconfigurable processor where connections and settings of circuit cells within an LSI can be reconfigured is also possible. 
     Further, if integrated circuit technology comes out to replace LSI&#39;s as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology. Application of biotechnology is also possible. 
     The disclosures of Japanese Patent Application No. 2008-281388 filed on Oct. 31, 2008 and Japanese Patent Application No. 2009-083043 filed on Mar. 30, 2009, including the specifications, drawings and abstracts, are incorporated herein by reference in their entirety. 
     Industrial Applicability 
     The radio terminal apparatus, the radio base station apparatus and the channel signal forming method according to the present invention are useful to prevent deterioration of the quality in downlink resource allocation information by reducing the frequency of processing including adding zero information to downlink resource allocation information when an uplink component band and a plurality of downlink component bands associated with the uplink component band.