JPH11177648A - Data transmission system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data transmission system with which data can be more efficiently transmitted by more reducing damage in the quality of data caused by noises generated on a transmission line concerning information sources having the different levels of data importance. SOLUTION: The importance level of data from a data source is discriminated by an importance level discriminating part 11, and a mapping method with the different probability of data error corresponding to the importance level is selected by a mapping selecting part 12. In this case, the data of high importance level are allocated to the symbol of low transmission error probability. At a mapping part 13, based on the mapping method selected by the mapping selecting part 12, mapping is performed and afterwards, data are modulated by a modulation part 14 and transmitted. A receiver traces a process inverse to the process of transmission processing performed at a transmitter, namely, a received signal is demodulated by a demodulation part 21, afterwards, demapped and decoded by a demapping part 22 according to a select signal generated by a mapping selecting part 23 based on the importance level discriminated by an importance level discriminating part 24.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] 1. Field of the Invention [0002] The present invention relates to data transmission technology, and more particularly, to data communication (including wired and wireless).
High-speed, high-efficiency transmission system.

[0002]

2. Description of the Related Art As a prior art relating to the data transmission technique, there are Japanese Patent Application Laid-Open No. 9-149258 "Image Communication Method" and Japanese Patent Application Laid-Open No. 9-172413 "Variable Rate Speech Coding System". The two conventional examples described above are systems in which the data transmission system is changed according to the error rate in the transmission path. In the "image communication method",
The low-frequency component and the high-frequency component of an image are separated, and the error correction method is changed according to the importance of data. However, it does not relate the symbol error rate or the mapping method itself to the data importance. Further, in the other "variable rate speech coding system", the transmission rate is changed according to the error rate of the transmission path, so that only the data of high importance is transmitted. However, the present invention is not related to the symbol error rate or the mapping method itself.

[0003]

In conventional data communication, all data has been treated as having the same importance. However, in actual use, data having different importance levels are often exchanged. For example, when image data or audio data is transmitted as frequency component data using discrete cosine transform or the like, high frequency components are data closer to noise than low frequency components that greatly affect the entire image.
In each frequency component, data with high power is an important component for reproduction of an image or sound, but data with low power does not contribute much to reproduction of an image or sound. The present invention has been made in view of the above-mentioned problems in the related art, and it is more effective for information sources having different degrees of importance of data that noise generated on a transmission line impairs data quality. It is an object of the present invention to provide a data transmission system capable of performing efficient data transmission.

[0004]

According to a first aspect of the present invention, in a data transmission system for transmitting data using symbols, the setting of the symbols used for transmission is performed by using a predetermined symbol arrangement having different transmission error probabilities. Performing according to the mapping to be performed, among the data to be transmitted, assigning high importance data to a symbol having a low probability of transmission error in the mapping, and among the data to be transmitted, assigning low importance data to the transmission error in the mapping. It is characterized by assigning to a symbol having a high probability.

According to a second aspect of the present invention, in a data transmission system for transmitting data using symbols, the setting of the symbols used for transmission is performed in accordance with a mapping that takes a predetermined symbol arrangement with different transmission error probabilities. The data to be framed, and in the data to be framed and transmitted, the entire high-priority frame is assigned to a symbol having a low probability of transmission error in the mapping, and among the data to be transmitted, the low-priority data is It is characterized by assigning to a symbol having a high probability of a transmission error in the mapping.

According to a third aspect of the present invention, in a data transmission system for transmitting data using symbols, the setting of the symbols used for transmission is performed in accordance with a mapping that takes a predetermined symbol arrangement with different transmission error probabilities. During the period in which high-importance data is transmitted, the data is assigned to a mapping that takes a symbol arrangement with a low probability of transmission error in the mapping, and the low-importance data is transmitted among the data to be transmitted. During this period, the data is allocated to mapping in which the probability of transmission errors in the mapping is high and a symbol arrangement with a high transmission rate is adopted.

According to a fourth aspect of the present invention, in the data transmission system according to the second or third aspect, the data to be transmitted is obtained by subjecting an original image to a discrete cosine transformation and entropy encoding the quantized data. And transmitting the coded image data, wherein the low-frequency component of the image is the high-priority data and the high-frequency component of the image is the low-priority data.

According to a fifth aspect of the present invention, in the data transmission system according to the second or third aspect, the data to be transmitted is image encoded data obtained by hierarchically encoding an original image, and the image encoded data is transmitted. In this case, the low-resolution data of the image is the high importance data, and the high-resolution data of the image is the low importance data.

According to a sixth aspect of the present invention, in the data transmission system according to the second or third aspect, the data to be transmitted is converted into audio encoded data obtained by converting original audio information into frequency components and quantizing the data. When transmitting the coded audio data, the low-frequency component of the audio is the high-priority data, and the high-frequency component of the audio is the low-priority data.

According to a seventh aspect of the present invention, in the data transmission system according to the first aspect, the data to be transmitted is audio encoded data obtained by PCM encoding of original audio information, and the audio encoded data is transmitted. In this case, data having a large voice amplitude is regarded as high importance data, and data having a small voice amplitude is regarded as low importance data.

According to an eighth aspect of the present invention, in the data transmission system according to the first aspect, the data to be transmitted is audio encoded data obtained by CELP encoding original audio information, and the audio encoded data is transmitted. In this case, data having a large gain component of the encoded voice data is defined as high importance data, and data having a small gain component of the encoded voice data is defined as low importance data.

According to a ninth aspect of the present invention, in the data transmission system according to the second or third aspect, the data to be transmitted is converted into audio encoded data obtained by converting original audio information into frequency components and quantizing the data. When transmitting the voice-encoded data, among the frequency components of the voice-encoded data, it is assumed that a high-power frequency component is defined as high-importance data and a low-power frequency component is defined as low-importance data. It is a characteristic.

According to a tenth aspect of the present invention, in the data transmission system according to the second or third aspect, the data to be transmitted is coded image data obtained by converting original image information into frequency components and quantizing the image information. When transmitting the image-encoded data, among the frequency components of the image-encoded data, it is assumed that a frequency component having a high power is regarded as high-priority data, and a frequency component having a low power is regarded as low-importance data. It is a characteristic.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS When transmitting digital data by modulating digital data regardless of whether it is wired or wireless, data is transmitted by allocating data to symbols and transmitting the symbols. For example, 8-level PSK modulation (PSK: Ph
In ase shift keying, symbols are transmitted by mapping the symbols on the phase space as shown in FIG. 1 and allocating 3-bit data to the symbols A to H. In addition, 8-level PAM modulation (PAM: Pulse Amplitude Modura)
2), the symbol A on the intensity level axis as shown in FIG.
ＨH and transmit a symbol. Usually, these inter-symbol distances are the same, although there are differences in parameters depending on the modulation method such as phase, intensity and frequency.

By the way, in general, when a certain symbol is transmitted, deterioration occurs on a transmission path from a transmitter at a transmission source to a receiver at a partner side, and a transmission error occurs. For example, when white Gaussian noise is added on the transmission path to the PAM modulation as shown in FIG. 2, the receiving side may receive a symbol erroneously as shown in a perspective area portion as shown in FIG. In this example, the symbol error probability P _e
Can be calculated using the tail function Q of a normal distribution,

[0016]

(Equation 1)

Can be expressed as Here, the inter-symbol distance = 2d and the noise variance σ ² . The above equation is
It indicates that the symbol error rate decreases as the inter-symbol distance increases. In addition to this example, the error rate generally decreases as the inter-symbol distance increases. The present invention takes advantage of this property and manipulates the error rate of each symbol by adjusting the inter-symbol distance so that important data has a low error rate and non-critical data has a high error rate. The transmission rate is increased by increasing the error rate.

A-law or μ-law is used for audio information.
When transmitting PCM-encoded data using, for example,
The original voice information is converted into data by logarithmic conversion as shown in FIG. As can be seen from FIG. 4, if 1 and 2 or 7 and 8 are mistaken, a large error will be transmitted, but if 4 and 5 are erroneously decoded, there will be a large difference from the original voice information. Not be. That is, the degree of importance differs depending on the data. However, when this data is transmitted using the mapping of FIGS. 1 and 2, all symbols are transmitted with the same error probability. Therefore, in the method according to the invention, for example,
As shown in the mapping on the phase space by the eight-valued PSK in FIG. 5, mapping is performed such that the inter-symbol distance is different for each symbol, and data having high importance is associated with the symbol (A, H) that is not easily erroneous. Important data can be made harder to make errors. When such mapping is performed, the error rate increases as a whole, but a certain level of sound quality can be ensured even at a noise level that cannot be heard with the mapping of FIG.

Similarly, when data having continuity such as audio data and image data is converted to frequency component data using discrete cosine transform or the like and transmitted, the low frequency component data is converted to the high frequency component data. It is more important data than data. However, unlike the case of PCM-coded data of voice information, instead of transmitting “highly important data or less important data”, “highly important data and less important data” are transmitted. Will do. Also, when transmitted as frequency component data, the original data is framed, so that data of high importance and data of low importance are sent every certain period.

FIG. 6 shows this state. When the audio data on the time axis of a certain frame (see FIG. 6A) is converted into a frequency component (see FIG. 6B) and the data is transmitted continuously, the frequency components f1, f2, f3 ... fn
(Set as f1 <f2 <f3... Fn) are repeatedly transmitted. At this time, if the data of all the frequency components is transmitted using the same symbol mapping, both the important low-frequency components and the low-frequency high-frequency components have the same error rate and
Transmitted at speed. On the other hand, as shown in the example of FIG. 7, mapping (FIG. 7A) is performed in accordance with the importance of data (see FIG. 7A).
(See (b)) itself, that is, the low-frequency component (f _{1 to} f _{n / 2} ) is QPSK, and the high-frequency component is 8-level PS.
When mapped as K, important low-frequency components can be transmitted with less error than high-frequency components. In the example of FIG. 7, the transmission speed is the same as that in the case where all the frequency components are transmitted by the six-valued PSK, but the error rate of the low-frequency component is low even under stronger noise. Some sound quality can be maintained. Alternatively, as compared with the case where all frequency components are transmitted by quaternary PSK, the example of FIG. 7 can transmit with a transmission capacity of ／, although the sound quality is slightly sacrificed.

FIG. 8 illustrates an example of another method for transmitting important low-frequency components more easily than the high-frequency components. In this example, the important data f ₁ (low frequency component) and the less important data f _{n / 2 +1} (high frequency component) are paired in the data (see FIG. 8A) to form one symbol. Is transmitted as. The symbol mapping is shown in FIG. 8 (b), where important data is transmitted as quadrants and less important data is transmitted using four signal points in that quadrant. As can be seen from FIG. 8, the important data has a larger inter-symbol distance than the less important data (the former is the inter-quadrant distance, and the latter is the inter-quadrant distance. Take).

In audio data and image data decomposed into frequency components, low-frequency components are important, and at the same time, high-power components are important. In addition, CELP coding (CE
LP (Code-Excited Linear Predictive Coding) speech data mainly consists of data indicating a codebook and data representing a gain component thereof. Larger data is more important than data having a smaller gain component. By setting an error rate according to the importance for data having such different importance, the present invention provides higher-speed transmission while being resistant to noise or not significantly deteriorating data quality. .

The present invention is not limited to audio information and image information,
Applicable to all data of different importance. In the example, PSK and PAM have been mainly described.
In other modulation schemes, the relationship between the inter-code distance and the error rate is the same, and is applicable.

FIG. 9 is a block diagram of a transmission / reception system as an implementation example of the system according to the present invention. The importance determining unit 11 determines the importance of the data from the data source,
To change the mapping itself, the mapping selection unit 1
In step 2, a mapping method is selected and changed. The mapping unit 13 performs mapping based on the mapping method selected by the mapping selection unit 12, and then modulates and transmits the modulated data by the modulation unit 14. The receiver follows the reverse process of the transmission process performed by the transmitter, that is, after demodulating the received signal by the demodulation unit 21, the importance determination unit 24.
The demapping unit 22 performs demapping and decoding according to the selection signal generated by the mapping selection unit 23 based on the importance determined in step (1).

[0025]

According to the first aspect of the present invention, in a system for transmitting data using symbols, when transmitting data having different degrees of importance, a symbol having a different transmission error probability set according to the degree of importance. With the same transmission speed, data can be transmitted without significantly deteriorating the quality of data even on a transmission path in which larger noise exists. Alternatively, higher-speed transmission can be performed without significantly deteriorating data quality.

According to a second aspect of the present invention, in a system in which data is framed and data is transmitted using symbols, when data having different degrees of importance is transmitted, the probability of a transmission error differs according to the degree of importance. By allocating the set symbols to each frame, in the case of the same transmission rate, even in a transmission path where a larger noise is present, the data quality is not significantly impaired, and by associating the frames with the symbols, the efficiency is improved. Can be transmitted. Or, while maintaining the quality of the data,
Enables higher-speed transmission.

According to the third aspect of the present invention, in a system for transmitting data using symbols, when transmitting data having different degrees of importance, the transmission periods are divided according to the degree of importance of the data, and each period has a different degree of importance. By assigning symbols with different transmission error probabilities in accordance with the above, at the same transmission rate, even in a transmission path where there is greater noise, the data quality is not significantly impaired, and the same symbol can be transmitted within a period. , Stable transmission is possible. Alternatively, higher-speed transmission can be performed without significantly deteriorating data quality.

Operation and Effect Corresponding to Claim 4: In addition to the operation and effect corresponding to Claims 2 and 3, the transmission of low-frequency components among the frequency components of the original image ensures that greater noise is present. The transmission of the image can also transmit the outline of the image.

Operation and Effect Corresponding to Claim 5: In addition to the operation and effect corresponding to Claims 2 and 3, the low-resolution component of the original image is reliably transmitted, so that even in a transmission line where a larger noise exists. , Can give an overview of the image.

Operation and Effect Corresponding to Claim 6: In addition to the operation and effect according to Claims 2 and 3, by ensuring low frequency components among the frequency components of the original voice, larger noise is present. The summary of the audio information can be transmitted also on the transmission path.

Operation and Effect Corresponding to Claim 7 In addition to the operation and effect corresponding to claim 1, by reliably transmitting data with a large amplitude in the information of the original voice, a larger noise is present. The outline of the audio information can be transmitted also on the transmission path.

Operation and Effect Corresponding to Claim 8 In addition to the operation and effect corresponding to claim 1, by transmitting data having a large gain component in the information of the original sound, larger noise is present. The transmission of the voice information can be conveyed also in the transmission path that performs the communication.

Operation and Effect Corresponding to Claim 9 In addition to the operation and effect according to Claims 2 and 3, in addition to the transmission of the frequency component having a large power among the frequency components of the original sound, a larger noise can be obtained. Can transmit the summary of the voice information even in the transmission path where the communication information exists.

Operation and effect corresponding to claim 10: claim 2
In addition to the functions and effects corresponding to (3) and (3), among the frequency components of the original image, the frequency components having a large power are reliably transmitted, so that the outline of the image information is transmitted even in a transmission path where a larger noise exists. be able to.

[Brief description of the drawings]

FIG. 1 shows symbols A to 8 on a phase space based on 8-ary PSK.
2 shows the mapping of H.

FIG. 2 shows mapping of symbols A to H on an intensity level axis by an 8-level PAM.

FIG. 3 is a diagram illustrating a symbol error due to noise in PAM modulation.

FIG. 4 shows the level of logarithmic conversion data of audio information.

FIG. 5 shows mapping of symbols A to H on a phase space by 8-ary PSK according to the present invention.

FIG. 6 is a diagram for explaining a method of transmitting audio data as a frequency component.

FIG. 7 is a diagram illustrating an embodiment in which the data transmission system according to the present invention is used for the transmission of FIG. 6;

FIG. 8 illustrates another example of a method for transmitting important low-frequency components more error-prone than high-frequency components.

FIG. 9 is a block diagram showing a transmission / reception system of an implementation example of the data transmission system according to the present invention.

[Explanation of symbols]

11 ... importance determination unit, 12 ... mapping selection unit, 13 ...
Mapping unit, 14 modulation unit, 21 demodulation unit, 22 demapping unit, 23 mapping selection unit, 24 importance determination unit.

Claims (10)

[Claims] 1. In a data transmission system for transmitting data using symbols, the setting of the symbols used for transmission is performed according to a mapping that takes a predetermined symbol arrangement with a different probability of transmission error, and the data to be transmitted is Assigning high importance data to a symbol having a low probability of transmission error in the mapping, and allocating low importance data to a symbol having a high transmission error probability in the mapping among the data to be transmitted. Data transmission system. 2. In a data transmission system for transmitting data using symbols, the setting of the symbols used for transmission is performed in accordance with a mapping that takes a predetermined symbol arrangement with different transmission error probabilities, and the data to be transmitted is framed. The data to be framed and transmitted
A method of allocating an entire frame of high importance to a symbol having a low probability of a transmission error in the mapping, and allocating data of a low importance to a symbol having a high probability of a transmission error in the mapping in the data to be transmitted. Transmission system. 3. In a data transmission system for transmitting data using symbols, the setting of the symbols used for transmission is performed according to a mapping that takes a predetermined symbol arrangement with different transmission error probabilities, and the data to be transmitted is The period during which high importance data is transmitted, the data is allocated to a mapping that takes a symbol arrangement with a low probability of transmission error in the mapping, and the low importance data is transmitted during the transmission. Has a high probability of transmission error in the mapping,
A data transmission system characterized by assigning to a mapping that takes a symbol arrangement with a high transmission rate. 4. The data transmission system according to claim 2, wherein the data to be transmitted is image-encoded data obtained by subjecting an original image to discrete cosine transform, and quantizing the data to entropy encoding. A data transmission system, wherein, when transmitting encoded image data, a low-frequency component of an image is the high-priority data and a high-frequency component of the image is the low-priority data. 5. The data transmission system according to claim 2, wherein said data to be transmitted is image encoded data obtained by hierarchically encoding an original image, and said image encoded data is transmitted when said image encoded data is transmitted. A data transmission system wherein low-resolution data is the high-priority data and high-resolution image data is the low-priority data. 6. The data transmission system according to claim 2, wherein the data to be transmitted is converted into audio encoded data obtained by converting original audio information into frequency components and quantizing the data. A low-frequency component of the voice is the high-priority data, and a high-frequency component of the voice is the low-priority data. 7. The data transmission system according to claim 1, wherein the data to be transmitted is audio encoded data obtained by PCM encoding original audio information, and the audio encoded data is transmitted when the audio encoded data is transmitted. A data transmission system characterized in that data having a large amplitude is defined as data having high importance and data having a small amplitude of voice is data having low importance. 8. The data transmission system according to claim 1, wherein the data to be transmitted is obtained by converting original audio information to CELP.
When transmitting the encoded voice data, the data having a large gain component of the encoded voice data is converted into the data having high importance, and the data having the small gain component of the encoded voice data is transmitted. A data transmission system characterized by low-importance data. 9. The data transmission system according to claim 2, wherein the data to be transmitted is converted into audio encoded data obtained by converting original audio information into frequency components and quantizing the data. When transmitting the voice data, the voice data is characterized in that, among the frequency components of the voice coded data, the frequency component having a high power is regarded as high importance data, and the frequency component having a low power is regarded as low importance data. Transmission system. 10. The data transmission system according to claim 2, wherein the data to be transmitted is coded image data obtained by converting original image information into frequency components and quantizing the data. Data transmission, wherein, among the frequency components of the coded image data, the frequency components having high power are regarded as high-priority data, and the frequency components having low power are regarded as low-priority data. system.