Abstract: A wireless communication apparatus having a wireless communication function capable of using a plurality of transmission rates. The wireless communication apparatus includes utilization-factor calculation section for calculating a utilization factor of a wireless transmission path through which wireless communication is performed using the wireless communication function and determination section for determining a transmission rate at least on the basis of the utilization factor calculated by the utilization-factor calculation section.

Abstract: A wireless communication apparatus having a wireless communication function capable of using a plurality of transmission rates. The wireless communication apparatus includes utilization-factor calculation means for calculating a utilization factor of a wireless transmission path through which wireless communication is performed using the wireless communication function; and determination means for determining a transmission rate at least on the basis of the utilization factor calculated by the utilization-factor calculation means.

Abstract: The mobile communication terminal of the present invention comprises an amplitude regulator 3 regulating the amplitudes of signals of the DPDCH, DPCCH, and HS-DPCCH, a transmission-power controller 17 controlling the power-distribution ratio for the adjustment of transmission power of the individual transmission channels, and a priority-channel selector 18 choosing a priority channel from among the individual transmission channels. If the total transmission power of the individual transmission channels is going to exceed the maximum transmission power, the transmission-power controller 17 determines the power-distribution ratio among the individual transmission channels by adjusting the transmission power of the priority transmission channel to a power level demanded by a base station on the one hand and adjusting the transmission power of the non-priority channel so as to confine the total transmission power to the maximum transmission power on the other hand.

Abstract: Disclosed is a method and an apparatus for controlling transmission electric power capable of minimizing a decrease in the amount of maximum transmission electric power without degrading an adjacent channel leakage power ratio when code-multiplexing additional control information with data and main control information. A mobile device checks values of gain factors ?d and ?c when performing code multiplexing to transmit signals from channels DPDCH to transmit data, DPCCH to transmit main control information, and HS-DPCCH to transmit additional control information. A maximum transmission electric power is decreased at a plurality of levels based on the check result and a ratio (?hs) between the gain factors ?c and ?hs. It may be preferable to check the presence or absence of transmission data instead of the gain factor ?d. In this case, when no transmission data is available, the maximum transmission electric power is decreased at a plurality of levels based on ?hs.

Abstract: Control information, which is transmitted through a circuit different from the one used for the transmission of a plurality of pieces of information to be multiplexed, is analyzed. When the analysis results in a determined intra-TTI data length of information having longer Transmission Time Interval, it is determined whether a range of values that TFCI may take is limited or not. If the determination provides a positive result, the intra-TTI data length of information having a longest Transmission Time Interval which has been determined by the latest TFCI decoding is used as a base for limiting TFCI candidates to be decoded next, so as to decode the TFCI.

Abstract: A signal processing device and method are provided. The signal processing device and method perform maximum-likelihood decoding of data transmitted at an arbitrary data rate among a plurality of predetermined data rates after error detection coding and error correction coding.

Abstract: Provides a normalizing apparatus that normalizes input signals to a turbo decoder without significantly increasing a size of a circuit. An input signal buffer (341) obtains a sum S for N pieces of input signal data I(i). An input data averaging part (342) obtains an average A by dividing the sum S by the number of data N. A divider (343) obtains normalized data I(i)/A by dividing the input signals I(i) by the average A. A weighting part (345) multiplies the normalized data I(i)/A with a weighting coefficient ?, which is determined based on a ratio of a number of input data and a number of output data in rate matching. As a result, the normalization is made possible. Because a signal receiving quality does not need to be determined, an increase in circuit size is inhibited.

Abstract: Disclosed is a method and an apparatus for controlling transmission electric power capable of minimizing a decrease in the amount of maximum transmission electric power without degrading an adjacent channel leakage power ratio when code-multiplexing additional control information with data and main control information. A mobile device checks values of gain factors ?d and ?c when performing code multiplexing to transmit signals from channels DPDCH to transmit data, DPCCH to transmit main control information, and HS-DPCCH to transmit additional control information. A maximum transmission electric power is decreased at a plurality of levels based on the check result and a ratio (?hs) between the gain factors ?c and ?hs. It may be preferable to check the presence or absence of transmission data instead of the gain factor ?d. In this case, when no transmission data is available, the maximum transmission electric power is decreased at a plurality of levels based on ?hs.

Abstract: A data reception device is provided with: a puncture rate detection element to detect the puncture rate of received data, an interpolation element to interpolate bits decimated at the detected puncture rate, a deinterleaving element to restore interleaved data to the original arrangement, and a turbo-decoding element, while variably setting the length of the learning interval according to the puncture rate detected by the puncture rate detection element, to input sliding window data and the data of the above learning interval following the data of the sliding window to the data processed by the interpolation element and deinterleaving element, and to perform recursive operations to decode the data of the sliding window. The valid received signal contained in the learning interval can be maintained approximately constant even if the puncture rate changes.

Abstract: A data reception device is provided with: a puncture rate detection element to detect the puncture rate of received data, an interpolation element to interpolate bits decimated at the detected puncture rate, a deinterleaving element to restore interleaved data to the original arrangement, and a turbo-decoding element, while variably setting the length of the learning interval according to the puncture rate detected by the puncture rate detection element, to input sliding window data and the data of the above learning interval following the data of the sliding window to the data processed by the interpolation element and deinterleaving element, and to perform recursive operations to decode the data of the sliding window. The valid received signal contained in the learning interval can be maintained approximately constant even if the puncture rate changes.

Abstract: The mobile communication terminal of the present invention comprises an amplitude regulator 3 regulating the amplitudes of signals of the DPDCH, DPCCH, and HS-DPCCH, a transmission-power controller 17 controlling the power-distribution ratio for the adjustment of transmission power of the individual transmission channels, and a priority-channel selector 18 choosing a priority channel from among the individual transmission channels. If the total transmission power of the individual transmission channels is going to exceed the maximum transmission power, the transmission-power controller 17 determines the power-distribution ratio among the individual transmission channels by adjusting the transmission power of the priority transmission channel to a power level demanded by a base station on the one hand and adjusting the transmission power of the non-priority channel so as to confine the total transmission power to the maximum transmission power on the other hand.

Abstract: Provides a normalizing apparatus that normalizes input signals to a turbo decoder without significantly increasing a size of a circuit. An input signal buffer (341) obtains a sum S for N pieces of input signal data I (i). An input data averaging part (342) obtains an average A by dividing the sum S by the number of data N. A divider (343) obtains normalized data I (i)/A by dividing the input signals I (i) by the average A. A weighting part (345) multiplies the normalized data I(i)/A with a weighting coefficient &agr;, which is determined based on a ratio of a number of input data and a number of output data in rate matching. As a result, the normalization is made possible. Because a signal receiving quality does not need to be determined, an increase in circuit size is inhibited.

Abstract: A signal processing device and method are provided. The signal processing device and method perform maximum-likelihood decoding of data transmitted at an arbitrary data rate among a plurality of predetermined data rates after error detection coding and error correction coding.

Abstract: Control information, which is transmitted through a circuit different from the one used for the transmission of a plurality of pieces of information to be multiplexed, is analyzed. When the analysis results in a determined intra-TTI data length of information having longer Transmission Time Interval, it is determined whether a range of values that TFCI may take is limited or not. If the determination provides a positive result, the intra-TTI data length of information having a longest Transmission Time Interval which has been determined by the latest TFCI decoding is used as a base for limiting TFCI candidates to be decoded next, so as to decode the TFCI.

Abstract: A signal processing apparatus to perform maximum likelihood decoding for the data transmitted thereto at one of plural predetermined data rates. The data rates are selected in a predetermined order, and a maximum likelihood decoding process is executed to regard the data rate of the received data as the selected data rate, and a predetermined decision value is calculated on the basis of a predetermined metric value obtained through the above process. Then the decision value is compared with a first threshold value, and a decision is made, on the basis of the result of such comparison, as to whether the selected data rate is the true data rate of the received data.