KR100446753B1 - Adaptive modulation coding apparatus for mobile communication device - Google Patents

Abstract

The present invention relates to an adaptive modulation coding apparatus of a mobile communication terminal. The present invention relates to an adaptive modulation coding (AMC) in which a BLAST (Bell-Lab Layered Space-Time) having an independent layer structure for each transmitting antenna is combined, By selecting a transmission antenna accordingly and applying an independent Modulation Coding Scheme (MCS) level, the transmission rate of the forward link can be improved, thereby improving the transmission rate of the forward link. To this end, the present invention provides an encoder for encoding transmission data; A channel interleaver for interleaving data output from the encoder; A modulator for modulating data output from the channel interleaver; A transmission antenna selection unit for outputting data output from the modulator to a transmission antenna selected by a control signal; A BLAST processing unit which sequentially receives data output from the transmission antenna selection unit, discriminates and outputs the data to a corresponding transmission antenna; A BLAST decoder for BLAST decoding the data received through the antenna; A channel estimator for receiving the BLAST decoded data, estimating channel state information for each antenna, outputting channel estimation values according to the antennas, and outputting a control signal for selecting an optimal transmission antenna based on the channel state information; An MCS level selector for applying a control signal for selecting an optimal scheme and coding type within an MCS threshold value to an encoder, a channel interleaver, and a modulator for each antenna according to the channel estimation value for each antenna output from the channel estimator; A demodulator for demodulating the decoded data output from the BLAST decoder by the channel estimate value; A channel deinterleaver for channel deinterleaving demodulated data output from the demodulator; The decoder decodes data output from the channel deinterleaver and outputs information bits.

Description

ADAPTIVE MODULATION CODING APPARATUS FOR MOBILE COMMUNICATION DEVICE}

The present invention relates to a method for increasing a forward link rate of a mobile communication terminal. In particular, a combination of an adaptive modulation coding (AMC) and a BLAST (Bell-Lab Layered Space-Time) having an independent layer structure for each transmitting antenna is optimized. Adaptive modulation coding apparatus of mobile communication terminal to improve forward link rate by selecting transmission antenna according to channel condition and applying independent modulation coding scheme (MCS) level to improve forward link rate It is about.

In general, Adaptive Modulation Coding (AMC) has a configuration as shown in FIG. 1 and feeds back the channel estimation value of a receiver to a transmitter to transmit in an optimal modulation and coding form.

That is, the transmission data is encoded through the encoder 1, interleaved through the channel interleaver 2, modulated by the modulator 3, and then transmitted and output.

Next, the data received from the counterpart through the antenna ANT is demodulated by the demodulator 4 and the signal estimator SNR is detected by the channel estimator 5.

Accordingly, the demodulated data is deinterleaved through the channel deinterleaver 7, decoded and output through the decoder 8, and modulated / coded selector 6 by the channel estimate detected by the channel estimator 5. ) Controls the sender component with the optimal modulation and coding scheme.

At this time, the modulation coding selector (MCS: Modulation Coding Scheme 6), as shown in Figure 2 allows to achieve the optimal transmission rate in consideration of four cases.

However, the AMC has a problem that the rate performance is improved but the error performance is not improved by simply changing the modulation and coding scheme according to channel conditions.

BLAST, a system structure technique, is classified into two types, D (Diagonal) -BLAST and V (Vertical) -BLAST.

In both of the above schemes, modulation and coding are performed by parallelizing transmission data sequentially input by the number of transmission antennas. As data continues to be input, a bit string, that is, a layer, is formed as many as the number of transmission antennas.

As shown in FIG. 3, the structure of the transmitter of the mobile communication terminal to which the D-BLAST is applied is configured such that data output from one specific layer is periodically transmitted through another antenna. Diagonal transmission on the view.

However, the method of applying the D-BLAST has a problem of improving the error performance but not improving the transmission rate.

The structure of the transmitting terminal of the mobile communication terminal applying the V-BLAST, as shown in Figure 4, is configured to transmit the data of each layer to its own transmission antenna, and has a vertical form on the space, time axis, such V The method of applying -BLAST also has the problem of improving the error performance but not improving the transmission rate.

In order to solve this problem, in recent years, by combining a BLAST (Bell-Lab Layered Space-Time) having an independent layer structure for each transmitting antenna to Adaptive Modulation Coding (AMC), the transmission rate of the forward link is improved. Since the same MCS level is applied, there is a limit to the improvement of the rate performance.

Therefore, the present invention has been created to solve the above-described problems, and combines the BLAST (Bell-Lab Layered Space-Time) having an independent layer structure for each transmit antenna to AMC (Adaptive Modulation Coding) Adaptive modulation coding of mobile communication terminal to improve forward link rate by selecting transmission antenna according to channel condition and applying independent modulation coding scheme (MCS) level to improve forward link rate The object is to provide a device.

1 is a block diagram showing the configuration of a conventional AMC (Adaptive Modulation Coding).

2 is an exemplary view for explaining a selection condition of an MCS selector in the AMC of FIG.

3 is a schematic diagram showing the structure of a transmitting end of a conventional D-BLAST;

4 is a schematic diagram showing the structure of a transmitting end of a conventional V-BLAST;

5 is a block diagram showing a configuration of an adaptive modulation coding apparatus of a mobile communication terminal of the present invention.

6 is an exemplary view showing transmission performance in the case where an independent MCS level is applied to each transmission antenna and the same MCS level is applied to all transmission antennas according to the present invention.

*** Description of the symbols for the main parts of the drawings ***

10: encoder 20: channel interleaver

30: modulator 40: BLAST processing unit

50: BLAST decoder 60: Channel estimator

70: demodulator 80 channel deinterleaver

90: decoder 100: MCS level selector

200: transmit antenna selector

The present invention for achieving the above object is an encoder for encoding the transmission data; A channel interleaver for interleaving data output from the encoder; A modulator for modulating data output from the channel interleaver; A transmission antenna selection unit for outputting data output from the modulator to a transmission antenna selected by a control signal; A BLAST processing unit which sequentially receives data output from the transmission antenna selection unit, discriminates and outputs the data to a corresponding transmission antenna; A BLAST decoder for BLAST decoding the data received through the antenna; A channel estimator for receiving the BLAST decoded data, estimating channel state information for each antenna, outputting channel estimation values according to the antennas, and outputting a control signal for selecting an optimal transmission antenna based on the channel state information; An MCS level selector for applying a control signal for selecting an optimal scheme and coding type within an MCS threshold value to an encoder, a channel interleaver, and a modulator for each antenna according to the channel estimation value for each antenna output from the channel estimator; A demodulator for demodulating the decoded data output from the BLAST decoder by the channel estimate value; A channel deinterleaver for channel deinterleaving demodulation data output from the demodulator; And a decoder for decoding the data output from the channel deinterleaver and outputting information bits.

Hereinafter, the operation and effects of the adaptive modulation coding apparatus of the mobile communication terminal according to the present invention will be described with reference to the accompanying drawings.

5 is a block diagram showing the configuration of an embodiment of an adaptive modulation coding apparatus of a mobile communication terminal according to the present invention.

As shown in Fig. 5, the adaptive modulation coding apparatus of the mobile communication terminal of the present invention comprises: an encoder 10 for encoding transmission data; A channel interleaver (20) for interleaving data output from the encoder (10); A modulator (30) for modulating data output from the channel interleaver (20); A transmit antenna selector 200 for outputting data output from the modulator 30 to a transmit antenna selected by a control signal; A BLAST processing unit (40) which sequentially receives data output from the transmitting antenna selection unit (200), discriminates them, and outputs them to a corresponding transmission antenna; A BLAST decoder 50 for BLAST decoding the data received through the antenna; A channel estimator (60) for receiving the BLAST decoded data, estimating channel state information for each antenna, outputting channel estimation values according to the antennas, and outputting a control signal for selecting an optimal transmission antenna based on the channel state information; Based on the channel estimation value for each antenna output from the channel estimator 60, a control signal for selecting an optimal scheme and coding type within the MCS threshold for each antenna, the encoder 10, the channel interleaver 20, and the modulator. An MCS level selector 100 applied to 30; A demodulator (70) for demodulating the decoded data output from the BLAST decoder (50) by the channel estimate value; A channel deinterleaver (80) for channel deinterleaving demodulation data output from the demodulator (70); The decoder 90 decodes the data output from the channel deinterleaver 80 and outputs information bits. The operation of the present invention will be described.

First, the BLAST decoder 50 performs BLAST decoding on data received through an antenna and applies it to the channel estimator 60 and the demodulator 70, and the channel estimator 60 receives the BLAST decoded data. The channel state information is estimated for each antenna, and the channel estimation value according to the antenna is applied to the MCS level selector 100, and a control signal for selecting an optimal transmission antenna as the channel state information is applied to the transmission antenna selector 200.

Accordingly, the MCS level selector 100 uses the channel estimation value output from the channel estimator 60 and the channel estimation value for each antenna to output the optimal scheme and coding type within the MCS threshold for each antenna. The control signal for selection is applied to the encoder 10, the channel interleaver 20, and the modulator 30.

Accordingly, the encoder 10, the channel interleaver 20, and the modulator 30 process data in an optimal manner and coding form within an MCS threshold selected by a control signal of the MCS level selector 100. That is, the encoder 10 encodes the transmission data and interleaves it through the channel interleaver 20, and then modulates and outputs the data output from the channel interleaver 20 in the modulator 30.

In this case, the transmission antenna selector 200 outputs the data output from the modulator 30 to the transmission antenna selected by the control signal of the channel estimator 60.

Subsequently, the BLAST processing unit 40 sequentially receives data output from the transmitting antenna selection unit 200, discriminates and transmits the data output through the corresponding transmission antenna.

In other words, the present invention combines a BLAST (Bell-Lab Layered Space-Time) having an independent layer structure for each transmit antenna to AMC (Adaptive Modulation Coding), and selects a transmission antenna according to an optimal channel condition. By applying the Modulation Coding Scheme (MCS) level, the transmission rate of the forward link is improved.

6 shows the performance when the AMC and BLAST are integrated and the MCS level is independently applied to each transmission antenna according to the present invention, and the MCS level is applied to each transmission antenna rather than the MCS level is equally applied to all transmission antennas. Independent application shows that the data rate is improved.

The specific embodiments or examples made in the detailed description of the present invention are intended to clarify the technical contents of the present invention to the extent that they should not be construed as limited to these specific embodiments and should not be construed in consultation. Various changes can be made within the scope of.

As described above, the adaptive modulation coding apparatus of the mobile communication terminal combines an adaptive modulation coding (AMC) with a BLAST (Bell-Lab Layered Space-Time) having an independent layer structure for each transmitting antenna and an optimal channel. By selecting a transmission antenna according to a condition and applying an independent Modulation Coding Scheme (MCS) level, the transmission rate of the forward link can be improved, thereby improving the transmission rate of the forward link.

Claims (1)

An encoder for encoding transmission data; A channel interleaver for interleaving data output from the encoder; A modulator for modulating data output from the channel interleaver; A transmission antenna selection unit for outputting data output from the modulator to a transmission antenna selected by a control signal; A BLAST processing unit which sequentially receives data output from the transmission antenna selection unit, discriminates and outputs the data to a corresponding transmission antenna; A BLAST decoder for BLAST decoding the data received through the antenna; A channel estimator for receiving the BLAST decoded data, estimating channel state information for each antenna, outputting channel estimation values according to the antennas, and outputting a control signal for selecting an optimal transmission antenna based on the channel state information; An MCS level selector for applying a control signal for selecting an optimal scheme and coding type within an MCS threshold value to an encoder, a channel interleaver, and a modulator for each antenna according to the channel estimation value for each antenna output from the channel estimator; A demodulator for demodulating the decoded data output from the BLAST decoder by the channel estimate value; A channel deinterleaver for channel deinterleaving demodulation data output from the demodulator; And a decoder for decoding the data output from the channel deinterleaver and outputting information bits.