JP2003224617A - Apparatus and method for communication - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To actualize a high transmission rate by avoiding discarding of a packet even in the case of abrupt change of a transmission line state and preventing resending processing. <P>SOLUTION: Modulation systems and the number of error bits of received packets are stored in a received packet information storage part 28A by transmission source addresses of the received packets and a transmission destination address detection part 29 retrieves the transmission destination address of a transmitted packet from the received packet information storage part. A modulation system determination part 30A determines a modulation system which has higher efficiency than the modulation system stored in the received packet information storage part when the number of error bits of the same address as the transmission destination address is 0, determines the same modulation system as the modulation system stored in the received packet information storage part when the number of error bits is within a specified range, determines a modulation system with lower efficiency than the modulation system stored in the received packet information storage part when the number of error bits exceeds the specified range. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication device and a communication method for error-correcting a transmission packet, modulating and transmitting the packet.

[0002]

2. Description of the Related Art Ethernet (R) (IEEE 802.3) is known as a method for transmitting a variable-length packet between a plurality of communication devices connected to a transmission path that can be logically regarded as a bus type. Frame error on Ethernet (R)
A check (Frame Error Check: FEC) is added, and a packet including an error is detected by FEC. In this method, a packet including an error is discarded, the upper layer performs a retransmission process, and the discarded packet is retransmitted.

Further, there is a HomePNA system as a system for modulating and transmitting a variable length packet. An error detection code is also added to the HomePNA method packet, and the packet containing the error is discarded and retransmitted. This method has a function of controlling the modulation method by discarding a packet due to an error, and selects a modulation method that does not cause packet discard according to the situation of the transmission path to perform communication.

[0004]

However, in the above-mentioned conventional communication method, in the case of a transmission path situation in which a signal is erroneous, packet discard occurs, and loss data is protected by retransmission. This reduces the overall transmission rate of communication. In addition, the HomePNA modulation method control method does not allow detailed control according to the status of the transmission line,
There was a problem that it was not possible to follow a sudden change in the transmission path condition.

The present invention solves the above-mentioned conventional problems. Even if there is a sudden change in the transmission path condition, packet discard can be avoided, retransmission processing can be prevented from occurring, and a high transmission rate can be realized. An object of the present invention is to provide an excellent communication device and communication method that can be performed.

[0006]

In order to achieve the above object, a communication device of the present invention has a storage means for storing a modulation method and an error bit number of a received packet for each source address of the received packet, and a transmitted packet. Is searched for from the storage means, and the number of error bits of the same address is 0
In this case, a modulation method having a higher efficiency than the modulation method stored in the storage means is determined, and when the number of error bits is within a predetermined range, the same modulation method as that stored in the storage means is determined. A modulation scheme determination means for determining a modulation scheme having a lower efficiency than the modulation scheme stored in the storage means when the number of error bits exceeds the predetermined range; and the transmission packet determined by the modulation scheme determination means. And a means for transmitting after modulating with a modulation method (claim 1). With the above configuration, the modulation method of the transmission packet of the same destination is determined based on the modulation method of the received packet and the number of error bits, so that the optimum modulation method can be selected even when there is a sudden change in the transmission path condition. Yes, for this reason, packet discard is avoided to prevent retransmission processing,
A high transmission rate can be realized.

In order to achieve the above object, the communication apparatus of the present invention has a storage unit for storing the modulation scheme of the received packet, the number of error bits and the packet length for each source address of the received packet, and the transmitted packet. Of the destination address of the same address is divided by the packet length of the number of error bits of the same address, and when the error rate is 0, a modulation scheme having a higher efficiency than the modulation scheme stored in the storage means is determined. If the error rate is within a predetermined range, the same modulation method as the one stored in the storage means is determined, and if the error rate exceeds the predetermined range, it is lower than the modulation scheme stored in the storage means. A configuration including a modulation method determining unit that determines an efficiency modulation method, and a unit that modulates the transmission packet with the modulation method determined by the modulation method determining unit and transmits the modulated packet. And (claim 2). With the above configuration, the modulation method of the transmission packet of the same destination is determined based on the modulation method of the reception packet and the error rate, so the optimum modulation method can be selected even when there is a sudden change in the transmission path condition. Therefore, it is possible to avoid packet discard, prevent the occurrence of retransmission processing, and realize a high transmission rate.

In order to achieve the above-mentioned object, the communication device of the present invention further comprises a storage means for accumulating and storing the modulation scheme of the received packet for each source address of the received packet, the number of error bits and the packet length. , A higher efficiency than the modulation method stored in the storage means when the destination address of the transmission packet is retrieved from the storage means and the cumulative error rate obtained by dividing the cumulative error bit number of the same address by the cumulative packet length is 0. And the same modulation method stored in the storage means when the cumulative error rate is within a predetermined range, and when the cumulative error rate exceeds the predetermined range, the storage means is stored in the storage means. Modulation method determining means for determining a modulation method having a lower efficiency than the stored modulation method, and the transmission packet is modulated by the modulation method determined by the modulation method determining means. And means for signal, was constructed and having (claim 3). With the above configuration, the modulation method of the transmission packet of the same destination is determined based on the modulation method of the reception packet and the cumulative error rate, so that the optimum modulation method can be selected even when there is a sudden change in the transmission path condition. Therefore, packet discard can be avoided, retransmission processing can be prevented from occurring, and a high transmission rate can be realized.

In order to achieve the above object, the communication apparatus of the present invention has a storage means for storing the error correction capability and the number of error bits of the received packet for each source address of the received packet, and the destination of the transmitted packet. The address is retrieved from the storage means, and when the number of error bits of the same address is 0, an error correction capacity higher than the error correction capacity stored in the storage means is determined, and when the number of error bits is within a predetermined range. The same error correction capability as the error correction capability stored in the storage unit is determined, and when the number of error bits exceeds the predetermined range, an error correction capability having an efficiency lower than the error correction capability stored in the storage unit is determined. An error correction capability determining means for determining and an error correcting capability for transmitting the transmission packet with the error correction capability determined by the error correction capability determining means are transmitted. Configuration and the that (claim 4). With the above configuration, since the error correction ability of the same destination packet is determined based on the error correction ability of the received packet and the number of error bits, the optimum error correction ability is selected even if there is a sudden change in the transmission path condition. Therefore, packet discard can be avoided, retransmission processing can be prevented from occurring, and a high transmission rate can be realized.

In order to achieve the above object, the communication apparatus of the present invention has a storage unit for storing the error correction capability of the received packet, the number of error bits and the packet length for each source address of the received packet, and the transmission unit. The destination address of the packet is searched from the storage means, and when the error rate obtained by dividing the number of error bits of the same address by the packet length is 0, an error correction ability higher than the error correction ability stored in the storage means is determined. If the error rate is within a predetermined range, the same error correction capability as the error correction capability stored in the storage unit is determined, and if the error rate exceeds the predetermined range, the error stored in the storage unit is determined. An error correction capability determining means for determining an error correction capability having an efficiency lower than the correction capability and an error correction capability for the transmission packet determined by the error correction capability determining means are erroneous. And means for transmitting corrections to, and configuration and having (claim 5). With the above configuration, the error correction capability of the transmission packet of the same destination is determined based on the error correction capability of the reception packet and the error rate. Therefore, the optimum error correction capability is selected even if there is a sudden change in the transmission path condition. Therefore, packet discard can be avoided, retransmission processing can be prevented from occurring, and a high transmission rate can be realized.

In order to achieve the above object, the communication apparatus of the present invention has a storage means for accumulating and storing the error correction capability of the received packet, the number of error bits and the packet length for each source address of the received packet. And the destination address of the transmission packet is searched from the storage means, and when the cumulative error rate obtained by dividing the cumulative error bit number of the same address by the cumulative packet length is 0, the error correction capability stored in the storage means A high error correction capability is determined, and when the cumulative error rate is within a predetermined range, the same error correction capability as the error correction capability stored in the storage means is determined, and when the cumulative error rate exceeds the predetermined range, the error correction capability is determined. The error correction capability determining means for determining an error correction capability having a lower efficiency than the error correction capability stored in the storage means, and the transmission packet by the error correction capability determining means. And means for transmitting at the determined error correction capability and the error correction, and configuration and having (claim 6). With the above configuration, the error correction capability of the transmission packet of the same destination is determined based on the error correction capability of the received packet and the cumulative error rate, so the optimum error correction capability can be selected even when there is a sudden change in the transmission path condition. Therefore, it is possible to avoid packet discard and prevent retransmission processing.
A high transmission rate can be realized.

In order to achieve the above-mentioned object, the communication method of the present invention modulates a transmission packet by the modulation method described in any one of claims 1 to 3 and transmits it. The error correction capability described in any one of 1 to 6 is used for error correction and transmission (claim 7). With the above method, it is possible to select the optimum modulation method and error correction capability even if there is a sudden change in the transmission path condition, and therefore, avoid packet discard and prevent retransmission processing,
A high transmission rate can be realized.

[0013]

BEST MODE FOR CARRYING OUT THE INVENTION <First Embodiment> An embodiment of the present invention will be described below with reference to the drawings. 1 is a block diagram showing Embodiment 1 of a communication device according to the present invention,
FIG. 2 is a flowchart for explaining the modulation method determination process of the communication device of FIG.

The communication device 20A according to the first embodiment observes the received packet addressed to itself and stores the modulation method and the error bit number of the received packet for each source address, and the contents thereof are the same. It is updated when the next packet from the address is received. Here, the transmission packet modulation scheme is “transmission modulation scheme TXM”, the reception packet modulation scheme is “reception modulation scheme RXM”, and the packet transmission modulation scheme TXM has N stages with different modulation efficiencies.
The one with the lowest modulation efficiency is TXM = 1, and the one with the highest modulation efficiency is TXM = N. Here, the modulation method generally has a high transmission rate if it is highly efficient, and has a low error resistance to noise. On the contrary, if the efficiency is low, it has a trade-off performance that the transmission rate is low and the error resistance against noise is high.

In the communication device 20A shown in FIG. 1, the error correction code addition section 21 adds an error correction code to the input digital transmission packet data TD, and the transmission function section 22.
Transmits the transmission packet data from the error correction code adding unit 21 to the transmission line 1 after modulating the transmission packet data by the transmission modulation system TXM determined by the modulation system determination unit 30A.

The reception function unit 23 inputs the signal on the transmission line 1, demodulates it, converts it into a digital signal, and outputs an error correction unit 25.
Detects and corrects an error in the digital signal output of the reception function unit 23 and outputs it as the reception packet data RD, and the error bit number RX of the packet corresponding to the input timing of the gate signal from the own device addressed packet detection unit 27.
E is output to the received packet information storage unit 28A.

The modulation method detection unit 24 detects the reception modulation method RXM of the packet received by the reception function unit 23, and the modulation method information of the reception packet corresponding to the input timing of the gate signal from the packet detection unit 27 addressed to itself. The RXM is output to the received packet information storage unit 28A. The transmission source address detection unit 26 detects the transmission source address of the reception packet RD output by the error correction unit 25, and determines the transmission source address of the packet corresponding to the input timing of the gate signal from the own device addressed packet detection unit 27 as the reception packet. Information storage unit 28
Output to A. The own device addressed packet detection unit 27 detects a packet addressed to the own device from the received packet RD output from the error correction unit 25, and outputs the gate signal in the received packet section to the modulation method detection unit 24, the error correction unit 25 and the source address. Output to the detection unit 26.

The received packet information storage unit 28A stores the received modulation method RXM and the error bit number RXE input from the modulation method detection unit 24 and the error correction unit 25, respectively, of the received packet input from the source address detection unit 26. The data is sorted according to the source address and stored. The destination address detection unit 29 detects the destination address of the transmission packet data TD, and the modulation method determination unit 30A determines the transmission modulation method TXM of the transmission packet TD and notifies the transmission function unit 22 as shown in detail in FIG. To do.

First, the operation when receiving a packet will be described. Packets input from the transmission line 1 are received by the reception function unit 23.
Is demodulated in step S4 and is output to the error correction unit 25 as digital received packet data. The modulation method detection unit 24 detects the modulation method RXM applied to the received packet at this time. The error correction unit 25 performs error correction on the received packet data, outputs the corrected packet data RD, and counts the corrected number of bits RXE. The source address detection unit 26 detects the source address of the corrected packet data RD. The own device addressed packet detection unit 27 detects the transmission destination address of the corrected packet data RD, and when the transmission destination address matches the address of the own device, detects the gate signal by the modulation method detection unit 24.
And outputs it to the error correction unit 25 and the transmission address detection unit 26.

The modulation method detecting section 24, the error correcting section 25, and the transmission address detecting section 26 output the information detected by each when the gate signal is input to the received packet information storage section 28A. If the input source address is among those stored in the past, the reception packet information storage unit 28A stores the reception modulation method R corresponding to the source address.
Overwrites the values entered in the record of XM and error bit number RXE. If the source address is not among those stored in the past, the source address is newly recorded, and the modulation method RXM and the error bit number RXE are recorded in association with it.

Next, the operation during transmission will be described. The transmission destination address detection unit 29 detects the transmission destination address from the transmission packet data TD and determines whether or not a packet has been received from the transmission destination in the past.
Search and check the address recorded in A. If there is a match, the reception packet information storage unit 28A stores the reception modulation scheme RX recorded in association with the address.
On the other hand, when there is no match between M and the error bit number RXE, the fact is notified to the modulation method determination unit 30A. As shown in detail in FIG. 2, the modulation scheme determination unit 30A determines the transmission modulation scheme TXM and notifies it to the transmission function unit 22, and the transmission function unit 22 transmits the transmission packet with the modulation scheme TXM notified from the modulation scheme determination unit 30A. Modulate and output to transmission line 1.

Next, with reference to FIG. 2, the modulation method determination unit 30A
The process will be described in detail. First, the destination address detecting unit 29 detects the destination address of a packet to be transmitted (step S1), and the modulation method determining unit 3
0A searches the record of the source address of the packet received so far in the received packet information storage unit 28A for the same address (step S2). As a result of the search, when there is no record of the same address, it is assumed that the transmission modulation method TXM = 1, which has the highest noise resistance, although the transmission rate is lowered, as the packet is surely transmitted to the device whose transmission path status is unconfirmed without error. Determine this modulation method TXM
The transmission packet is modulated by and transmitted (step S2 → S
8).

When the same address is recorded as a result of searching the transmission destination address, a packet from the transmission destination address has been received in the past, and the reception modulation method RXM and the error bit number RXE recorded at that time are recorded. Is read (step S3). Then, the error bit number RXE is 0 (RXE
= 0), it is assumed that communication with a higher transmission rate is possible, and the transmission modulation method TXM is set to the reception modulation method RXM.
One-step higher efficiency modulation method (TXM = RXM + 1)
Is determined (steps S4 → S9). When the reception modulation method RXM = 1, the transmission modulation method TXM = 1 is determined (steps S5 → S9).

Further, when the error bit number RXE is equal to or less than SE (0 <RXE ≦ SE) with respect to the error bit number SE (SE is a positive integer) which does not exceed the error correction capability, a sufficient error occurs. The transmission modulation method TXM is the same modulation method (TXM) as the reception modulation method RXM, assuming that the occurrence can be allowed by the error correction capability and the occurrence of packet discard can be prevented.
= RXM) (steps S6 → S10). When the number of error bits RXE is larger than SE (RXE> SE), it is considered that the error occurrence may exceed the error correction capability. Therefore, the transmission modulation method TXM is received and modulated in order to further prevent the error occurrence due to noise although the transmission rate is reduced. Method RXM
Modulation system with lower efficiency by one step (TXM = RXM-1)
Is determined (steps S6 → S7).

By the above operation, it is possible to select the optimum modulation method TXM according to the error bit number RXE of the received packet while preventing the transmission rate from being lowered due to the packet discard and the retransmission.

<Second Embodiment> The second embodiment will be described with reference to FIGS. In the second embodiment, FIG.
As shown in FIG. 4, the received packet addressed to the own communication device 20B is observed and detected by the packet length coefficient unit 31 in addition to the modulation method RXM and the error bit number RXE of the received packet for each source address. Received packet length RXC
Is stored in the received packet information storage unit 28B. The content is updated when the next packet is received from the same source address. The modulation scheme determination unit 30B determines the transmission modulation scheme TXM by the processing shown in FIG. Note that FIG.
The same reference numerals are given to the same components as those in Embodiment 1 and the processing steps in FIG.

In FIG. 4, the destination address of the packet to be transmitted is detected (step S1),
The modulation method determination unit 30B is the reception packet information storage unit 28B.
The record of the source address of the packets received so far is searched for the same address (step S2). As a result of the search, if there is no record of the same address, it is assumed that the packet is surely transmitted to the device whose transmission line status is unconfirmed without error. The packet is transmitted (steps S2 → S8).

If the same address is recorded as a result of the address search, the packet from the destination address has been received in the past, and the reception modulation method RXM, the error bit number RXE, and the packet recorded at that time are received. The long RXL is read (step S3A), and then the error bit number RXE
Is divided by the packet length RXL and the error rate RXER = RXE
/ RXL is calculated (step S3B).

The error rate RXER is 0 (RXER =
In the case of 0), the transmission modulation system TXM is set to the reception modulation system RXM on the assumption that communication at a higher transmission rate is possible.
One-step higher efficiency modulation method (TXM = RXM + 1)
Is determined (steps S4A → S9). Also, RXM =
In the case of 1, TXM = 1 is determined (step S5 → S)
8). In addition, for the error rate value SER (SER is a positive real number) that does not exceed the error correction capability, the error rate RXE
When R is less than or equal to SER (0 <RXER ≦ SER), it is assumed that the error occurrence is sufficiently tolerable by the error correction capability and the occurrence of packet discard can be prevented, and TXM is the same modulation method as RXM (TXM = RXM). ) Is determined (steps S6A → S10). Further, when the error rate RXER is larger than SER (RXER> SER), it is considered that the error occurrence may exceed the error correction capability, and the transmission rate drops, but TXM is set to R in order to prevent the error occurrence due to noise.
A modulation method with one step lower efficiency than XM (TXM = RXM-
1) is determined (steps S6A → S7).

By the above operation, it is possible to select the optimum modulation method TXM according to the error rate RXER that can grasp the status of the transmission path without depending on the received packet length while preventing the transmission rate from decreasing due to packet discard and retransmission. You can

<Third Embodiment> A third embodiment will be described with reference to FIGS. In the third embodiment, FIG.
As shown in FIG. 6, first, when a packet addressed to the own device 20C is received, as in the second embodiment, the reception modulation method RXM, the error bit number RXE, and the packet length RXL are set for each source address of the packet. Detect (step S1
1, S12). If the detected source address is not among those previously recorded in the received packet information cumulative storage unit 28C, the detected source address and the RXM, RXE, and RXL are associated and the received packet information cumulative storage unit 28C is associated.
It is newly recorded in C (steps S13 → S14).

If the detected transmission source address is among those recorded in the reception packet information cumulative storage unit 28C in the past, the modulation method MRXM recorded in the past in association with the transmission source address and the modulation method currently detected RXM
Is compared with (step S13 → S15). MRXM
And RXM are the same, the error bit number RXE and the packet length RXL are respectively the received packet information cumulative storage unit 28.
The cumulative error bit number MRXE and the cumulative packet length MRXL previously recorded in C are cumulatively added to update the recording (steps S15 → S16). When the MRXM and the RXM are different, the MRXM, MRXE, and MRXL accumulated and stored in the reception packet information accumulation storage unit 28C are overwritten and updated with RXM, RXE, and RXL of the reception packet of this time (steps S15 → S17). ).

Further, in the third embodiment, the modulation scheme determination unit 30C determines the transmission modulation scheme TXM by the processing shown in FIG. 7 during transmission. It should be noted that the same components as those in the second embodiment having the same configuration in FIG. 5 and processing steps in FIG. In FIG. 7, first, similarly to the second embodiment, the destination address of the packet to be transmitted is detected (step S1), and then the modulation method determination unit 30C causes the received packet information cumulative storage unit 28C to store the data up to this point. Then, it is searched whether or not the same address exists in the record of the source address of the packet received in step S2.
If there is no record with the same address as a result of the search, TX
The transmission packet TD is modulated by the modulation method of M = 1 and transmitted (steps S2 → S8).

In the third embodiment, if the same address is recorded as a result of the address search, a packet from the destination address has been received in the past, and the recorded modulation method MRXM and accumulated error are recorded. The number of bits MRXE and the cumulative packet length MRXL are read (step S3
C), cumulative packet length M from cumulative error bit number MRXE
The cumulative error rate RXER is calculated by dividing RXL (step S3D). The cumulative error rate RXER is 0 (RX
When ER = 0), it is assumed that communication with a further increased transmission rate is possible, and TXM is determined to be a modulation method (TXM = MRXM + 1) that is one step more efficient than MRXM (steps S4A → S9). When MRXM = 1, T
XM = 1 is determined (steps S5 → S8). The error rate value SER (SE
R is a positive real number), when 0 <RXER ≦ SER, TXM = MRXM is determined (steps S6A → S1).
0), when RXER> SER, TXM = MRXM-1
Is determined (steps S6A → S7).

By the above operation, the transmission rate drop due to packet discard and retransmission can be prevented, and the error rate can be calculated over several packets without depending on the received packet length, so that the situation of the transmission line can be grasped more accurately. Therefore, the optimum modulation method TXM can be selected.

<Fourth Embodiment> Next, a fourth embodiment will be described with reference to FIGS. In Embodiment 4 (and Embodiments 5 and 6), instead of modulation method TXM,
The error correction system determination unit 32A determines the error correction capability TXC, and the error correction code addition unit 21 determines the error correction capability TXC.
It is configured to add the code of XC to the transmission packet TD. In the error correction method, if the error correction capability TXC is low, the number of error correction bits is small, but the number of redundant bits to be added to the packet is small, so that the packet data transmission rate is high. On the contrary, if you have high ability,
Although the number of error correction bits increases, the number of redundant bits added to a packet increases, so that the packet data transmission rate decreases, which is a trade-off property. Here, as the error correction capability TXC, N stages having different correction capabilities (N is an integer of 2 or more) are used, the highest correction capability is TXC = 1, and the lowest correction capability is TXC =. N.

A detailed description will be given with reference to FIG. First, as described above, the error correction code addition unit 21 causes the transmission packet T
The code of the error correction capability TXC determined by the error correction method determination unit 32A is added to D. Next, unlike the first to third embodiments, the transmission function unit 22 modulates the packet data from the error correction code addition unit 21 by a fixed modulation method and sends it out to the transmission line 1.

Next, the operation when receiving a packet will be described. The reception packet input from the transmission line 1 is demodulated by the reception function unit 23 and output to the error correction unit 25 as digital packet data. The error correction unit 25 performs error correction on the received packet data, outputs the corrected received packet data RD, counts the corrected error bit number RXE, and outputs the corrected error packet number RXE to the received packet information storage unit 28D. The information of the added redundant bit is output to the error correction capability detection unit 33. The error correction capability detection unit 33 detects the error correction capability RXC of the received packet RD based on this redundant bit information, and outputs the information to the received packet information storage unit 28D.

The other configuration is almost the same as that of the first embodiment. The source address detecting unit 26 detects the source address of the corrected packet data RD and outputs it to the received packet information storage unit 28D, and the received packet information is stored. The error correction capability RXC and the error bit number RXE are recorded for each source address in the storage unit 28D. Further, if the input source address is among those stored in the past, the received packet information storage unit 28D stores the values input to the record of the error correction capability RXC and the error bit number RXE associated with the source address. Overwrite. If the source address is not among those stored in the past, the source address is newly recorded and the error correction capability (method) RXC and the error bit number RXE are recorded in association with it.

Next, the processing of the error correction method determination unit 32A will be described with reference to FIG. First, the destination address of the packet TD to be transmitted is detected (step S1), and then the error correction method determination unit 32A stores the source address of the packet received so far in the received packet information storage unit 28D. It is searched whether there is the same address from the inside (step S2). As a result of the search, if there is no record of the same address, it is assumed that the packet is surely transmitted to the device whose transmission path status has not been confirmed without being discarded, and the transmission rate drops, but TXC = 1 which has the highest error correction capability. The transmission packet TD is error-corrected by the error correction method of No. 1 and the packet is transmitted (steps S2 → S8).
A).

When the same address is recorded as a result of the address search, the packet from the destination address has been received in the past, and the error correction capability RXC and the error bit number RXE recorded at that time are read ( Step S3
E) and RXE = 0, it is assumed that communication with a further increased transmission rate is possible, and TXC is determined to be an error correction method TXC = RXC + 1 having a one-step correction capability lower than RXC (steps S4 → S9A). When RXC = 1, RXC = 1 is determined (steps S5A → S8A).
Further, when 0 <RXE ≦ SE, it is assumed that the error occurrence is sufficiently tolerable by the error correction ability and the occurrence of the packet discard can be prevented, and the TXC is set to the error correction method (TXC = RXC) having the same ability as the RXC. Determine (step S6 → S1
0A). Further, when RXE> SE, it is considered that the error occurrence may exceed the error correction capability, and the transmission rate is lowered, but in order to prevent packet discard due to the error occurrence, T
XC is one step higher than RXC in error correction capability (TX
C = RXC-1) is determined (steps S6A → S7).
A).

By the above operation, the optimum error correction capability TXC can be selected in accordance with the error bit number RXE of the received packet while preventing the transmission rate from being dropped due to packet discard and retransmission.

<Fifth Embodiment> A fifth embodiment will be described with reference to FIGS. In the fifth embodiment,
This is a combination of the fourth and the fourth embodiments as shown in FIGS. That is, the destination address of the packet to be transmitted is detected (step S
1) Then, the error correction method determination unit 32B searches the received packet information storage unit 28E from the record of the source addresses of the packets received so far for the same address (step S2). As a result of the search, when there is no record of the same address, the packet is transmitted with the error correction capability of TXC = 1 (steps S2 → S8A).

If the same address is recorded as a result of the address search, the packet from the destination address has been received in the past, and the error correction capability RXC, the number of error bits RXE, and the packet length recorded at that time are recorded. RXL is read (step S3F), and the error rate RXER is calculated by dividing the error bit number RXE by the packet length RXL (step S3B). Then, when RXER = 0, TXC =
RXC + 1 (steps S4A → S9A), 0 <RX
When ER ≦ SER, TXC = RXC (step S
6A → S10A), when RXER> SER, TXC =
RXC-1 (steps S6A → S7A). Also,
When RXC = 1, RXC = 1 is determined (steps S5A → S8A).

By the above operation, the optimum error correction capability TXC is selected according to the error rate RXER which can grasp the status of the transmission path without depending on the received packet length while preventing the transmission rate from being dropped due to packet discard and retransmission. can do.

<Sixth Embodiment> A sixth embodiment will be described with reference to FIGS. In the sixth embodiment,
This is a combination of the fourth and third embodiments as shown in FIGS. Here, although the drawing corresponding to FIG. 6 of the third embodiment is omitted, the modulation method RX in FIG.
It is sufficient to replace M with the error correction method TXC. That is, the reception of the packet addressed to the own device 20F is observed, and when the packet addressed to the own device 20F is received, the source address of the received packet, the error correction capability RXC, the error bit number RXE, and the packet length RXL. To detect.

If the detected source address is not among those recorded in the reception packet information cumulative storage unit 28F in the past, the detected source address and RXC, RXE and R
Newly record in association with XL. If the detected transmission source address is among those recorded in the reception packet information cumulative storage unit 28F in the past, the error correction capability MRX recorded in the past in association with the transmission source address.
C is compared with the currently detected error correction capability RXC.
When MRXC and RXC are the same, RXE and RXL cumulatively add to the previously recorded error bit number MRXE and packet length MRXL, respectively, to update the record. MRX
When C and RXC are different, MRXC, MRXE, MRX
L is overwritten and updated with RXC, RXE, and RXL, respectively.

When this communication device 20F tries to transmit a packet, as shown in FIG. 13, the destination address of the packet to be transmitted is detected (step S1), and then the error correction method determination unit 32C receives it. The record of the source addresses of the received packets received and stored so far in the packet information accumulation storage unit 28F is searched for the same address (step S).
2). As a result of the search, when there is no record of the same address, the packet is transmitted with the error correction capability of TXC = 1 (steps S2 → S8A). If there is a record of the same address as a result of address search, error correction capability MRXC
And cumulative error bit number MRXE and cumulative packet length MRX
Read L (step S3G), cumulative error rate RXER
Is calculated (step S3D). And RXER = 0
If so, TXC = MRXC + 1 is determined (step S4
A → S9A), and when 0 <RXER ≦ SER, T
It is determined that XC = MRXC (steps S6A → S10
A), and when RXER> SER, TXC = MRX
C-1 is determined (steps S6A → S7A). Also,
When MRXC = 1, RXC = 1 is determined (steps S5B → S8A).

By the above operation, the transmission rate drop due to packet discard and retransmission can be prevented, and the error rate can be calculated over several packets without depending on the received packet length, so that the situation of the transmission line can be grasped more accurately. Therefore, the optimum error correction capability TXC can be selected.

[0050]

As described above, according to the first aspect of the present invention, since the modulation scheme of the transmission packet of the same destination is determined based on the modulation scheme of the reception packet and the number of error bits, abrupt transmission is performed. The optimum modulation method can be selected even if there is a change in the road condition, and therefore packet discard can be avoided, retransmission processing can be prevented from occurring, and a high transmission rate can be realized. According to the invention of claim 2,
Since the modulation method of the transmission packet of the same destination is determined based on the modulation method of the received packet and the error rate, it is possible to select the optimum modulation method even if there is a sudden change in the transmission path condition. It is possible to avoid packet discard, prevent retransmission processing, and realize a high transmission rate. According to the invention described in claim 3, since the modulation method of the transmission packet of the same destination is determined based on the modulation method of the reception packet and the cumulative error rate, it is optimal even if there is a sudden change in the transmission path condition. Modulation method can be selected, which prevents packet discard and prevents retransmission processing.
A high transmission rate can be realized. According to the invention as set forth in claim 4, since the error correction capability of the transmission packet of the same destination is determined based on the error correction capability of the reception packet and the number of error bits, even if there is a sudden change in the transmission path condition. It is possible to select the optimum error correction capability, which avoids packet discard and prevents retransmission processing.
A high transmission rate can be realized. According to the invention described in claim 5, since the error correction capability of the transmission packet of the same destination is determined based on the error correction capability of the reception packet and the error rate, it is optimal even when there is a rapid change in the transmission path condition. Error correction ability can be selected, and
It is possible to avoid packet discard, prevent retransmission processing, and realize a high transmission rate. According to the invention described in claim 6, since the error correction capability of the transmission packet of the same destination is determined based on the error correction capability of the received packet and the cumulative error rate, even if there is a sudden change in the transmission path condition. It is possible to select the optimum error correction capability, and thus it is possible to avoid packet discard, prevent the occurrence of retransmission processing, and realize a high transmission rate. According to the invention described in claim 7, it is possible to select the optimum modulation method and error correction capability even when there is a sudden change in the transmission path condition. Therefore, packet discard is avoided and retransmission processing occurs. And a high transmission rate can be realized.

[Brief description of drawings]

FIG. 1 is a block diagram showing a first embodiment of a communication device according to the present invention.

FIG. 2 is a flowchart for explaining a modulation method determination process of the communication device of FIG.

FIG. 3 is a block diagram showing a second embodiment of a communication device according to the present invention.

FIG. 4 is a flowchart for explaining a modulation method determination process of the communication device of FIG.

FIG. 5 is a block diagram showing a third embodiment of a communication device according to the present invention.

FIG. 6 is a flowchart for explaining a cumulative storage process of received packet information of the communication device of FIG.

FIG. 7 is a flowchart for explaining a modulation method determination process of the communication device of FIG.

FIG. 8 is a block diagram showing a fourth embodiment of a communication device according to the present invention.

9 is a flowchart for explaining an error correction capability determination process of the communication device of FIG.

FIG. 10 is a block diagram showing a fifth embodiment of a communication device according to the present invention.

11 is a flowchart for explaining an error correction capability determination process of the communication device of FIG.

FIG. 12 is a block diagram showing a sixth embodiment of a communication device according to the present invention.

13 is a flowchart for explaining an error correction capability determination process of the communication device of FIG.

[Explanation of symbols]

1 transmission lines 20A to 20F communication device 21 error correction code addition unit 22 transmission function unit 23 reception function unit 24 modulation method detection unit 25 error correction unit 26 source address detection unit 27 self-addressed packet detection units 28A, 28B, 28D, 28E Received packet information storage unit 28C, 28F Received packet information cumulative storage unit 29 Destination address detection unit 30, 30A to 30C Modulation method determination unit 31 Packet length counting unit 32, 32A to 32C Error correction method determination unit 33 Error correction capability detection Department

Claims (7)

[Claims] 1. A storage unit for storing the modulation scheme and the number of error bits of the received packet for each source address of the received packet, and a destination address of the transmitted packet is searched from the storage unit, and the number of error bits of the same address is searched. Is 0, a modulation scheme having a higher efficiency than the modulation scheme stored in the storage means is determined, and when the number of error bits is within a predetermined range, the same modulation scheme as the storage scheme stored in the storage means is determined. And a modulation scheme determining means for determining a modulation scheme having a lower efficiency than the modulation scheme stored in the storage means when the number of error bits exceeds the predetermined range, and the transmission packet is determined by the modulation scheme determining means. And a means for transmitting the data after being modulated by the modulated method. 2. A method for storing the modulation scheme of the received packet, the number of error bits and the packet length for each source address of the received packet, and a destination address of the transmitted packet are searched from the storage means, and the same address is obtained. When the error rate obtained by dividing the number of error bits of 1 by the packet length is 0, a modulation method having a higher efficiency than the modulation method stored in the storage means is determined, and when the error rate is within a predetermined range, the storage means is stored. A modulation method determining unit that determines the same modulation method as the stored modulation method, and determines an efficiency lower than the modulation method stored in the storage unit when the error rate exceeds the predetermined range; And a means for modulating a transmission packet by the modulation method determined by the modulation method determining means and transmitting the modulated packet. 3. A storage unit for accumulating and storing the modulation scheme of the received packet, the number of error bits and the packet length for each source address of the received packet, and the destination address of the transmitted packet are searched from the storage unit. When the cumulative error rate obtained by dividing the cumulative number of error bits at the same address by the cumulative packet length is 0, a modulation scheme having a higher efficiency than the modulation scheme stored in the storage means is determined,
When the cumulative error rate is within a predetermined range, the same modulation scheme as the modulation scheme stored in the storage means is determined, and when the cumulative error rate exceeds the predetermined range, the modulation scheme stored in the storage means is determined. A communication device comprising: a modulation method determining unit that determines a low-efficiency modulation method; and a unit that modulates the transmission packet with the modulation method determined by the modulation method determining unit and transmits the modulated packet. 4. Storage means for storing the error correction capability and the number of error bits of the received packet for each source address of the received packet, and a destination address of the transmitted packet is searched from the storage means, and the error bit of the same address is searched. When the number is 0, an error correction capability higher than the error correction capability stored in the storage unit is determined, and when the number of error bits is within a predetermined range, the same error correction capability stored in the storage unit is determined. Error correction capability determining means for determining a correction capability and determining an error correction capability having an efficiency lower than the error correction capability stored in the storage means when the number of error bits exceeds the predetermined range; A communication device having means for performing error correction with the error correction capability determined by the error correction capability determination means and transmitting. 5. A storage unit for storing the error correction capability of the received packet, the number of error bits and the packet length for each source address of the received packet, and the destination address of the transmitted packet are searched from the storage unit and are the same. When the error rate obtained by dividing the number of error bits of the address by the packet length is 0, an error correction ability higher than the error correction ability stored in the storage means is determined, and when the error rate is within a predetermined range, the storage means. An error correction capability that determines the same error correction capability as the error correction capability stored in the storage unit, and determines an error correction capability with a lower efficiency than the error correction capability stored in the storage unit when the error rate exceeds the predetermined range. A communication device comprising: capability determining means; and means for performing error correction on the transmission packet with the error correction capability determined by the error correction capability determining means and transmitting the packet. 6. A storage unit for accumulating and storing the error correction capability of the received packet, the number of error bits and the packet length for each source address of the received packet, and searching the destination unit for the destination address of the transmitted packet. If the cumulative error rate obtained by dividing the cumulative number of error bits at the same address by the cumulative packet length is 0, an error correction capability higher than the error correction capability stored in the storage means is determined, and the cumulative error rate is within a predetermined range. When the cumulative error rate exceeds the predetermined range, the same error correction capability as the error correction capability stored in the storage unit is determined, and the efficiency is lower than the error correction capability stored in the storage unit. Error correction capability determining means for determining error correction capability; and a means for error-correcting and transmitting the transmission packet with the error correction capability determined by the error correction capability determining means. Preparative has communication device. 7. The transmission packet is modulated by the modulation method according to any one of claims 1 to 3 and transmitted, or the error correction capability according to any one of claims 4 to 6. A communication method characterized by error-correcting and transmitting.