JP2000252841A5 - - Google Patents

Description

[Claims]
[Claim 1] An error correction circuit that receives a carrier signal that is punctured convolutional coded at a predetermined code rate of one or more, is carrier-modulated mapped by a predetermined modulation method, and is transmitted, and performs error correction and decoding. And
A demapping circuit that demodulates the received carrier signal according to the transmitted modulation method and converts it into demodulated data.
A metric conversion circuit that quantizes the demodulated data and converts it into metric data,
A depuncture circuit that complements the metric data according to the transmitted code rate and outputs it as depunctured data.
It is provided with a Viterbi decoding circuit that decodes the depunctured data by Viterbi and outputs the decoded data.
The metric conversion circuit
An error correction circuit characterized in that the demodulated data is quantized at a quantization level according to a combination of a transmitted modulation method and a coding rate and output as metric data.
2. The metric conversion circuit
When the function for converting the demodulated data into multi-valued metric data is a quantization step function, the claim is characterized in that the gradient of the quantization step function is switched according to the combination of the transmitted modulation method and the coding rate. Item 1. The error correction circuit according to item 1.
3. The metric conversion circuit
When the function for converting the demodulated data into multi-valued metric data is a quantization step function and the transmission capacity determined by the combination of the transmitted modulation method and the coding rate is the allowable transmission capacity, the allowable transmission capacity is large. The error correction circuit according to claim 1, wherein the gradient of the quantization step function is increased in the case, and the gradient of the quantization step function is decreased when the allowable transmission capacity is small.
4. An error correction circuit that receives a carrier signal that is convolutionally coded at a predetermined coding rate, is carrier-modulated mapped by a predetermined modulation method, and is transmitted, and performs error correction and decoding.
A demapping circuit that demodulates the received carrier signal according to the transmitted modulation method and converts it into demodulated data.
A metric conversion circuit that quantizes the demodulated data and converts it into metric data,
It is provided with a Viterbi decoding circuit that decodes the metric data by Viterbi and outputs the decoded data.
The metric conversion circuit
An error correction circuit characterized in that the demodulated data is quantized at a quantization level corresponding to a transmitted modulation method and output as metric data.
5. The metric conversion circuit
The error correction according to claim 4, wherein when the function for converting the demodulated data into multi-valued metric data is a quantization step function, the gradient of the quantization step function is switched according to the transmitted modulation method. circuit.
6. The metric conversion circuit
When the function that converts the demodulated data into multi-valued metric data is the quantization step function and the transmission capacity determined by the transmitted modulation method is the allowable transmission capacity, if the allowable transmission capacity is large, the quantum The error correction circuit according to claim 4, wherein the gradient of the modulation step function is increased, and when the allowable transmission capacity is small, the gradient of the quantization step function is decreased.
7. An error correction circuit that receives a carrier signal that is punctured convolutional coded at a predetermined one or more coding rates, is carrier-modulated mapped by a predetermined modulation method, and is transmitted, and performs error correction and decoding.
A demapping circuit that demodulates the received carrier signal according to the transmitted modulation method and converts it into demodulated data.
A metric conversion circuit that quantizes the demodulated data and converts it into metric data,
A depuncture circuit that complements the metric data according to the transmitted code rate and outputs it as depunctured data.
It is provided with a Viterbi decoding circuit that decodes the depunctured data by Viterbi and outputs the decoded data.
The metric conversion circuit
An error correction circuit characterized in that the demodulated data is quantized at a quantization level according to a transmitted coding rate and output as metric data.
8. The metric conversion circuit
The error according to claim 7, wherein when the function for converting the demodulated data into multi-valued metric data is a quantization step function, the gradient of the quantization step function is switched according to the transmitted coding rate. Correction circuit.
9. The metric conversion circuit
When the function for converting the demodulated data into multi-valued metric data is a quantization step function and the transmission capacity determined by the transmitted coding rate is the allowable transmission capacity, if the allowable transmission capacity is large, the above-mentioned The error correction circuit according to claim 7, wherein the gradient of the quantization step function is increased, and when the allowable transmission capacity is small, the gradient of the quantization step function is decreased.

0014.
[Means for solving problems]
The present invention receives a carrier signal that is punctured convolution-encoded at a predetermined one or more coding factors, carrier-modulated mapped by a predetermined one or more modulation methods, and transmitted, and error-corrected and decoded. A demapping circuit that demolishes the received carrier signal according to the transmitted modulation method and converts it into demodulated data, and a metric conversion that quantizes the demodulated data and converts it into metric data. The circuit, the depuncture circuit that complements the metric data according to the transmitted coding rate and outputs it as depunctured data, and the depunctured data that is bitabi-decrypted and the decoded data is output. The metric conversion circuit comprises a circuit, and is characterized in that the demodulated data is quantized at a quantization level according to a combination of a transmitted modulation method and a coding rate, and output as metric data.
Here, when the function for converting the demodulated data into multi-valued metric data is a quantization step function, the metric conversion circuit has a gradient of the quantization step function according to a combination of a transmitted modulation method and a coding rate. May be switched.
Here, the metric conversion circuit uses a function for converting the demodulated data into multi-valued metric data as a quantization step function, and a transmission capacity determined by a combination of a transmitted modulation method and a coding rate as an allowable transmission capacity. When the allowable transmission capacity is large, the gradient of the quantization step function may be increased, and when the allowable transmission capacity is small, the gradient of the quantization step function may be decreased.

The present invention is an error correction circuit that receives a carrier signal that is convoluted and coded at a predetermined coding rate, is carrier-modulated mapped by a predetermined one or more modulation methods, and is transmitted, and performs error correction and decoding. The demapping circuit that demolishes the received carrier signal according to the transmitted modulation method and converts it into demodulated data, the metric conversion circuit that quantizes the demodulated data and converts it into metric data, and the metric data. It includes a bitabi decoding circuit that decodes bitabi and outputs the decoded data, and the metric conversion circuit quantizes the demodulated data at a quantization level according to the transmitted modulation method and outputs it as metric data. It is a feature.
Here, when the function for converting the demodulated data into the multi-valued metric data is a quantization step function, the metric conversion circuit may switch the gradient of the quantization step function according to the transmitted modulation method. Good.
Here, when the function for converting the demodulated data into multi-valued metric data is a quantization step function and the transmission capacity determined by the transmitted modulation method is the allowable transmission capacity, the metric conversion circuit is said to have the allowable transmission capacity. When is large, the gradient of the quantization step function may be increased, and when the allowable transmission capacity is small, the gradient of the quantization step function may be decreased.

The present invention is an error correction that receives a carrier signal that is punctured convolution-encoded at a predetermined one or more coding rates, is carrier-modulated mapped by a predetermined modulation method, and is transmitted, and performs error correction and decoding. A demapping circuit that demolishes the received carrier signal according to a transmitted modulation method and converts it into demodulated data, a metric conversion circuit that quantizes the demodulated data and converts it into metric data, and the above. A depuncture circuit that complements the metric data according to the transmitted coding rate and outputs it as depunctured data, and a bitabi decoding circuit that bitabi-decodes the depunctured data and outputs the decoded data. The metric conversion circuit is characterized in that the demodulated data is quantized at a quantization level corresponding to the transmitted coding rate and output as metric data.
Here, when the function for converting the demodulated data into multi-valued metric data is a quantization step function, the metric conversion circuit switches the gradient of the quantization step function according to the transmitted coding rate. May be good.
Here, in the metric conversion circuit, when the function for converting the demodulated data into multi-valued metric data is a quantization step function and the transmission capacity determined by the transmitted coding rate is the allowable transmission capacity, the allowable transmission is performed. When the capacitance is large, the gradient of the quantization step function may be increased, and when the allowable transmission capacity is small, the gradient of the quantization step function may be decreased .