JP2001160824A - Wired and wireless mixed network data distributor and data distribution method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To keep an excellent distribution state by deciding combinations of a congestion state and a transmission error occurrence state so as to prevent both meaningless distribution deterioration and a data loss. SOLUTION: In a configuration of the distributor that distributes a packet to a terminal through a wired network and a wireless network, the distributor is provided with a rate control section that decreases a packet distribution rate when a congestion state and a state of no transmission error are decided based on both of discrimination of the congestion state obtained from a packet loss rate including a delay and decision of the transmission error state obtained from a transmission error rate and revises a distribution method into a prescribed distribution method when the congestion state and the presence of a transmission error are decided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multimedia transmission system connected by a network, and more particularly to a multimedia distribution control method and apparatus in a network environment in which a wireless communication network and a wired communication network coexist. Things.

[0002]

2. Description of the Related Art Conventionally, when congestion occurs in a packet network, means for suppressing the entire network traffic by discarding packets by a relay node in the packet network is generally employed. For this reason, a method of temporarily lowering the transfer rate in order to reduce network traffic has been adopted in a data transmitting terminal in order to reduce network traffic as much as possible when detecting congestion. As a first conventional example, for example, according to Japanese Patent Application Laid-Open No. 9-244975, a communication network, a server transmitting a series of numbered data via the communication network, and a server are connected via the communication network. In an information communication system consisting of communicating terminals, congestion is detected based on the ratio of the number of data transmitted from the server to the number of data received by the terminal, and when congestion is determined, the number of data per unit time transmitted to the terminal is controlled. Congestion was avoided by lowering the transfer rate.

As a second conventional example, for example, according to Japanese Patent Laid-Open No. Hei 9-116572, transmission delay control for monitoring and evaluating the state of a network and outputting a packet length change request to a packet length according to the evaluation result. A device is provided on a network, and when network congestion occurs, a transmission delay control device transmits a change request to a packet length shorter than the packet length at that time to a node connected to the network, and the node shortens the packet length to transmit the request from the node. Congestion was avoided by lowering the transfer rate of

In a packet network, if a bit error occurs in a part of packet data due to a transmission error, a packet is discarded by a relay node or a receiving terminal. At this time, the discarded packets are retransmitted. However, if the network condition is poor and the bit error rate is 1 / n, a packet having a length of n bits cannot be transmitted forever until the network condition improves. And there was a problem of repeating retransmission. Therefore, as a third conventional example, according to Japanese Patent Laid-Open No. 3-131143, for example, a retransmission counter for monitoring the packet retransmission rate is provided on the transmission side, and the packet length is changed based on the packet retransmission rate calculated by the retransmission counter. If the packet retransmission rate is larger than a preset reference value, the packet length is shortened to reduce the amount of transfer information.

As a fourth conventional example, according to Japanese Patent Laid-Open No. 11-46186, for example, an observation process for observing a data error occurrence pattern in a received signal in packet units, and a propagation situation is predicted from the data error occurrence pattern. Prediction processing is provided, and when the data error occurrence pattern is concentrated in the latter half of the packet, the error occurrence start position is determined, and the packet length is converted to be shorter than the error occurrence start position, thereby reducing the error occurrence. It is to try to make it.

[0006]

The conventional distribution control and its system are based on a wired packet communication network.
No consideration has been given to a network in which a wired packet communication network and a wireless packet communication network coexist. For this reason, all packets that could not be received by the receiving terminal were judged to be congested on the network, and the transmitting terminal reduced the transmission rate. However, since the bit error rate (BER) of a wireless packet network is much larger than that of a wired packet network, packet discarding due to a bit error occurs. However, the transmitting terminal judges this to be congestion, and lowers the transmission rate that does not need to be reduced.In applications such as video data and audio data that require a certain amount of data to be delivered in a certain period of time, image disturbances and audio interruptions may occur. There was a problem of causing it. Further, in a packet communication, if a bit error occurs in a part of the packet data, the entire packet is generally discarded. Therefore, in an environment with a high BER such as a wireless packet communication network, a packet loss rate becomes high. Therefore, measures were taken to minimize the effects of bit errors by shortening the packet length.However, the conventional method does not consider a network in which a wired packet communication network and a wireless packet communication network coexist. However, the packet length is changed only by determining the network congestion. Therefore, the packet loss rate in the wireless packet communication network increases, and as a result, necessary data becomes insufficient or delayed,
Similarly, there is a problem that the image is disturbed or the sound is interrupted.

Further, conventionally, when an error is detected between a transmitting terminal and a receiving terminal in a wireless packet network, the packet length is shortened to reduce the effect.
It does not consider a network in which a wired packet communication network and a wireless packet communication network coexist. Therefore, there is a problem that it is not possible to distinguish between an error in the wired packet communication network and an error in the wireless packet communication network and make a corresponding effective correction. Was. In the past, when the network was congested, the transfer rate of the data transferred from the transmitting terminal was reduced to cope with it, so when data is distributed to multiple receiving terminals, the rate is gradually increased for all receiving terminals. There has been a problem in that the effect is reduced, and consequently, the image is disrupted and the sound is interrupted in all terminals.

The present invention has been made to solve the above-described problems. In a network in which a wired packet communication network and a wireless packet communication network coexist, feedback data is analyzed and the cause is determined by the wired network and the wireless network. Each of them is distinguished and guessed, and is appropriately dealt with by allocating to network congestion and transmission errors in a wireless packet network. That is, good distribution is obtained by preventing both meaningless reduction of the distribution rate and data loss.

[0009]

SUMMARY OF THE INVENTION A wired / wireless mixed network data distribution apparatus according to the present invention has a configuration in which a packet is distributed to a terminal through a wired network and a wireless network. Based on both the determination of the congestion state and the determination of the transmission error state obtained from the transmission error rate, if it is determined that the state is congested and that there is no transmission error, the packet distribution rate is reduced, and in the congestion state, Further, a rate control unit for changing to a predetermined distribution method when it is determined that the transmission error is also provided.

[0010] Furthermore, the rate control unit is provided in a congested state,
When it is determined that the packet is also a transmission error, the packet length is shortened and then transmitted.

Further, a priority is set for the packet,
A distribution number control unit is provided in place of the rate control unit. When the distribution number control unit determines that the state is a congestion state and is not a transmission error, the distribution number control unit lowers the distribution number of the low priority packets. .

[0012] Furthermore, the priority of the packet and the location to which the terminal belongs are set in the packet, and the transmission error rate, the priority and the location information are combined to determine that the packet is a transmission error. Was shortened.

In a wired / wireless mixed network data distribution method according to the present invention, in a distribution system for distributing packets to terminals via a wired network and a wireless network, a step of obtaining a packet distribution delay time, a packet loss rate, and a transmission error rate; ,
A congestion determination step of determining a congestion state from a delay time and a packet loss rate, a transmission error determination step of determining a transmission error occurrence state from a transmission error rate, and congestion in the congestion determination step and no error in the transmission error step. And a step of lowering the packet distribution rate.

Further, the method further comprises a step of shortening the length of the packet and delivering the packet when it is determined that congestion has occurred in the congestion determination step and an error has occurred in the transmission error determination step.

Further, a priority is set for the packet,
When it is determined in the congestion determination step that there is no congestion and in the transmission error determination step that no error has occurred, the method includes a step of reducing the number of packets of the low-priority packets instead of reducing the packet delivery rate.

Further, the priority of the packet and the location to which the terminal belongs are set in the packet, and the transmission error rate is combined with the priority and the location information to determine the transmission error. With the step of shortening

[0017]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 The present invention describes a system that expresses the basic idea, that is, determines a cause occurrence site and performs a corresponding process. FIG. 1 is a diagram showing a system configuration according to the embodiment of the present invention. In the figure, 1
Is a distribution server that distributes multimedia data such as video and audio, 2 is a wired packet communication network to which the distribution server is connected, 31, 32, and 33 are mobile terminals that receive data transmitted from the distribution server, 4 Is the mobile terminal 31
A base station device for performing wireless communication with the base station device; and a gateway device for mutually converting the data and protocol of the wired packet communication network and the data and protocol of the base station device, and 6 a wireless network. FIG. 2 is a diagram illustrating an internal configuration of the distribution server according to the present embodiment. In the figure, 11
Is a network interface unit for connecting to the wired network 2, 12 is a data receiving unit that receives data received from the mobile terminals 31 to 33 via the network interface unit 11, and 13 is a data receiving unit 12
A reception status detection unit that detects a packet loss rate, a round trip delay time (RTT), and a transmission error rate of a packet transmitted by the distribution server from reception status information from the mobile terminal received in
14 is a congestion determining unit that determines network congestion from the packet loss rate obtained from the receiving status detecting unit 13 and RTT, and 15 is an error occurrence frequency on the wireless packet communication network from the transmission error rate obtained from the receiving status detecting unit 13. The transmission error determination unit 17 determines packetized data sent from the rate control and converts the packetized data to the network interface unit 11.
The data transmission unit 16 transmits data to the wired network and the wireless network based on information from the congestion determination unit and the transmission error determination unit, which are new important components in the present embodiment. It is a rate control unit that controls the distribution rate to the body terminal.

Next, the distribution server 1 including the rate control unit 16
3 will be described with reference to FIG. In the distribution server 1, in order to distribute the video data A to the mobile terminal 31, the rate control unit 16 controls the transfer rate V _normal to satisfy the normal reproduction of the video data A, and the data transmission unit 17 Supply data to The data transmission unit packetizes the supplied data in video frame units, adds the packet sequence number and the time stamp of this packet,
The destination address and the own address of the mobile terminal 31 are also added and supplied to the network interface unit 11. At this time, the number of packets transmitted at that time is cumulatively added to the number of transmitted packets Pn−1, and the number of packets Pn is held.
The supplied data packet reaches the gateway 5 via the wired network 2, is transmitted to the base station 4, and is received by the mobile terminal 31 via the wireless network. These processes are repeated until there is a stop request from the mobile terminal 31 to the distribution server 1. The mobile terminal 31 compares the sequence number added to the received packet with the last sequence number received so far and checks whether there is any packet loss. If the sequence numbers become discontinuous, it is determined that packet discarding has occurred, and the number of packets is cumulatively added to the number of packet losses PL _n−1 and stored as the number of packet losses PL _n . The mobile terminal 31
Can detect an error in a data packet received on the wireless network, and accumulates and holds the data packet discard due to an error that could not be avoided by retransmission or correction code as the number of transmission errors En.

Next, in order to obtain the reception status of the receiving terminal (mobile terminal) 31 separately from the data distribution, the distribution server 1 creates a reception status request packet in the data transmission unit 17. This reception status request packet is periodically executed at a predetermined cycle interval or at a cycle interval corresponding to the transfer rate _Vnormal . The data transmission unit 17 adds the current time Ts when supplying the reception status request packet to the network interface unit 11. The network interface unit 11 transmits the reception status request packet to the mobile terminal 31 in the same manner as the data distribution. When the receiving status request packet is received by the receiving terminal 31 in the same procedure as the data distribution, the receiving terminal 31 adds the number of received packets Rn and the number of lost packets L
n and the number of transmission errors En are added, and the packet is sent back to the distribution server 1 as a response.

The network interface unit 11 having received the reception status response packet transfers the data to the data receiving unit 12. The data receiving unit sends the reception status response packet to the reception status detection unit 13 with the current time Tr at the time of reception added. The reception status detection unit 13 obtains a round trip delay time RTTn, a packet loss rate PLRn, and a transmission error rate ERn from information in the reception status response packet. These values are calculated by the following equations (1) to (3) in step (S) 31 of FIG.
Is calculated by RTTn = Tr−Ts (1) PLRn = PLn / Pn (2) ERn = En / Pn (3) The reception status detection unit 13 notifies the packet loss rate PLRn and the round-trip delay time RTTn to the congestion determination unit 14, and calculates (3)
The transmission error rate ERn obtained in step (1) is notified to the transmission error determination unit 15.

In the congestion determination unit 14, the minimum round-trip delay time RTTm
holding in, RT across wired and wireless networks
Tn and RTTmin are compared by equation (4), and in S32, RTTn <RTTm
In the case of the in equation (4), RTTn is set to the value of RTTmin. On the other hand, a predetermined packet loss rate threshold Tp and a packet loss rate
PLRn is compared by equation (4), and if PLRn> Tp equation (5), it is determined that the congestion is temporary. If it is determined that the congestion is temporary, then the round-trip delay time threshold predetermined according to the transfer rate V _normal
Comparison is made in step S33 with Tr using equation (5). (RTTn / RTTm
in)> Tr expression (6), it is determined that congestion has occurred. If the congestion is determined, the congestion determination unit 14 notifies the rate control unit 16 of the occurrence of congestion. RTTn <RTTmin (4) PLRn> Tp (5) (RTTn / RTTmin)> Tr (6)

On the other hand, the transmission error determination unit 15 compares the transmission error threshold Te determined in advance according to the transfer rate V _normal with ERn in equation (7) in S34, and if ERn> Te equation (7), It is determined that a transmission error has occurred. If a transmission error has occurred, the transmission error determination unit 15 notifies the rate control unit 16 of the occurrence of the transmission error.

The rate control unit 16 determines whether or not to control the rate in the network estimation step S35 of the operation flow based on the notification information from the congestion determination unit 14 and the transmission error determination unit 15. Specifically, in the case of (congestion occurrence) and (no transmission error), the transfer rate V _normal currently being transferred is set to a predetermined amount dV
Alternatively, it is decreased by an amount dV _adaptive according to (RTTn / RTTmin). If there is congestion and a transmission error has occurred, there are several transmission processing options. For example, in the past the rate was reduced, but instead the transfer rate V
Keep the _normal without changing and continue the distribution. That is, it is assumed that no congestion has occurred. Or, change to a system to which an error check code such as ECC is added. Or shorten the transmission packet length.

As described above, since the transfer rate is controlled to be reduced only when the network is really congested, packet loss caused by a bit error in the radio network is not erroneously determined to be network congestion. It is possible to avoid a significant decrease in the transfer rate. When it is estimated that apparent congestion has occurred due to a transmission error in the wireless network, it is possible to correct the transmission error. As a result, the distribution of the video data and the audio data to the wireless network is supplied at a more stable rate than in the past, so that the quality of the video reproduction and the audio reproduction is improved as compared with the conventional case.

A correction method for shortening the length of a transmission packet when a transmission error in a wireless network can be considered as occurring will be described below. In S35 of FIG. 3, in the case of a congestion state and a state where a transmission error has occurred, that is, S33 and S33
If both are YES, the rate controller 16 sets 1
The packet length multiplied by the following correction coefficient α is used as the data transmission unit 1
Instruct 7. If (congestion occurs) and (no transmission error), it indicates that congestion has occurred in the wired network, so the value of the correction coefficient α is not changed (S35 ′ in FIG. 3). The data is transmitted to the mobile terminal 31 from the network interface unit 11 after being packetized in a short length Ln by the data transmission unit 17.

As described above, in order to determine the packet length in consideration of network congestion and radio network bit errors,
If the frequency of error occurrence in the wireless network increases, the effect of discarded packets, that is, the amount of discarded data, can be reduced by shortening the packet length. So
The quality of video reproduction and audio reproduction is improved as compared with the conventional case. Also, in the case of network congestion, the packet length up to that time is maintained, so that for video data and audio data that need to be transferred at a constant transfer rate, it is possible to suppress an extra increase in the number of packets due to a decrease in the packet length.

Embodiment 2 FIG. In the above embodiment, the transfer rate of the delivery data is controlled when it can be inferred that congestion is truly occurring in the wired network. Instead, the transfer rate is not controlled, and the delivery server distributes the data at the same time. An embodiment for controlling the number of distribution streams will be described. FIG. 4 is a diagram showing the internal configuration of the distribution server in this embodiment. In the figure, a network interface unit 11,
Data receiving unit 12, reception status detecting unit 13, congestion determining unit 1
4. Obtained transmission error The transmission error determination unit 15 and the transmitting data transmission units 17 and 20 control the number of distribution streams to the mobile terminals 31 to 33 based on information from the congestion determination unit and the transmission error determination unit. The distribution number control unit 21 is a session priority determination unit that sets the priority of each session when establishing a connection with the mobile terminals 31 to 33 and determines the priority of the session. The data transmission unit 17 to transmit is
The components are the same as those of the first embodiment and FIG.

Next, the operation will be described. Distribution server 1
Before performing data distribution to the mobile terminals 31 to 33 from, first, priorities are set for the connections of the mobile terminals 31 to 33 when the connection between them is established. The method of assigning priorities does not matter here, but for example, it is conceivable to set them according to a request from a mobile terminal. In the description of this operation, the priority is set to the highest priority for the sake of explanation> mobile terminal 31> mobile terminal 3
2> mobile terminal 33> assuming lowest priority.

The distribution server 1 distributes video data A to the mobile terminal 31, video data B to the mobile terminal 32, and video data C to the mobile terminal 33, respectively. Transfer rates V _normalA , V _normalB , satisfying normal reproduction of A, B and C,
At _VnormalC , the distribution number control unit 20 controls and supplies data to the data transmission unit 17. The data transmission unit packetizes the supplied data in video frame units,
In addition to adding the packet sequence number and the time stamp of the packet, the destination addresses and the own addresses of the mobile terminals 31 to 33 are also added and supplied to the network interface unit 11. At this time, the number of packets P _n-1A , P _n-1B ,
P _n-1C , accumulatively adds the number of packets transmitted at that time for each session, and calculates the number of packets P _nA , P _nB , P for each session.
Hold _nC . The supplied data packet reaches the gateway 5 via the wired network 2, is transmitted to the base station 4, and is received by the mobile terminals 31 to 33 via the wireless network. These processes are performed by the mobile terminals 31 to 3
3 until the distribution server 1 receives a stop request. The mobile terminals 31 to 33 compare the sequence number added to the received packet with the last sequence number received so far to check whether there is any packet loss. If the sequence numbers become discontinuous, it is determined that packet discarding has occurred, and the packet loss number PL
_The number of packets to _n−1 is cumulatively added and stored as a packet loss number PL _n . Also, since the mobile terminals 31 to 33 can detect errors in data packets received on the wireless network, data packets discarded due to errors that could not be avoided by retransmission or correction codes are cumulatively added and held as the number of transmission errors En.

Next, the distribution server 1 performs the above-described data distribution.
To obtain the receiving status of the receiving terminals 31 to 33 separately,
The reception status request packet is created by the data transmission unit 17.
You. Each reception status request packet is transmitted for a predetermined cycle.
Remote or transfer rate V_{norm alA}, V_normalB, V
_normalC, And is executed periodically at a cycle interval according to.
The data transmission unit 17 converts each reception status request packet
When supplying to the network interface unit 11
The presence time Ts is added. Network interface section
11 transmits the reception status request packet in the same manner as the above data distribution.
To the mobile terminals 31 to 33 as described above. Data distribution
To the receiving terminal 31 in the same procedure as
When the packet is received, the receiving terminals 31 to 33 receive the packet.
The number of packets received so far and the packet
Number Ln and the number of transmission errors En, and distribute the packet.
It is sent back to the communication server 1 as a response.

The network interface unit 11 that has received each reception status response packet transfers the data to the data reception unit 12. The data receiving unit adds the current time Tr at the time of reception and sends each reception status response packet to the reception status detection unit. The reception status detection unit 13 calculates the round trip delay time RTTn, the packet loss rate PLRn, and the transmission error rate ERn from the information in the reception status response packet in the same manner as in the first embodiment. The reception status detecting unit 13 receives the packet loss rates PLRnA, PR from the respective receiving terminals 31 to 31.
LRnB, PLRnC, and round-trip delay time RTTnA, RTTn
B and RTTnC are notified to the congestion determining unit 14, and the respective transmission error rates ERnA, ERnB, and ERnC are transmitted.
Notify to

The congestion determination unit 14 determines congestion in the same procedure as in the first embodiment. If the congestion is determined, the congestion determination unit 14 notifies the distribution number control unit 20 of the occurrence of congestion. On the other hand, transmission error determination section 15 determines the occurrence of a transmission error in the same procedure as in the first embodiment. When a transmission error occurs, the transmission error determination unit 15 notifies the distribution number control unit 20 of the occurrence of the transmission error.

The number-of-distributions control section 20 determines whether the number of distribution streams should be controlled based on the notification information from the congestion determination section 14 and the transmission error determination section 15. Specifically, in the case of (occurrence of congestion) and (no transmission error), that is, in S35 of FIG.
In the case of Yes in S33 and No in S34, it is determined that congestion has truly occurred in the wired network, and the distribution of low priority sessions is temporarily stopped based on information from the session priority determination unit. In this description, since the connection with the mobile terminal 33 has the lowest priority, the data distribution to the mobile terminal 33 is temporarily stopped. Note that, depending on the degree of the congestion state, it is possible to stop distribution of a plurality of sessions at once. In that case, the degree of congestion is estimated from each transfer rate and each round trip delay time, and the required number of sessions is obtained.

It is to be noted that, including the first embodiment, it is possible to set a priority and determine the occurrence of transmission errors strictly. FIG. 5 is a diagram showing a flow of an operation for determining a transmission error in the wireless network according to the present embodiment. In the present embodiment, location information is defined for each of the mobile terminals 31 to 33, and when the mobile terminals 31 to 33 are in the same location, the same location information is added. In this state, a response packet shown in FIG. 6 is returned in response to the reception status request packet from the distribution server. This is specifically the IETF RF
Using the RTCP packet defined in C1889, data is written in the extension part of 25. Distribution server 1
Receives this response packet, checks the transmission error in S41, and further determines in S42, S43 and S46 to S48 whether a transmission error has occurred and whether it is a discriminator.

As described above, when it can be considered that congestion is truly occurring only in the wired network, the quality of video reproduction and audio reproduction in all terminals is degraded by gradually lowering all distribution rates. Rather, by temporarily suspending data distribution for low-priority sessions, data can be continuously distributed to other high-priority terminals even if network congestion occurs. As a result, it is possible to guarantee the quality based on the priority while maintaining the quality of the sound reproduction. That is, it is possible to prevent erroneous determination due to occurrence of an error in the wireless network.
Also, it can be determined whether or not a transmission error has actually occurred in the wireless network, and corresponding processing can be performed.

[0036]

As described above, according to the present invention, in a system in which a wired network and a wireless network coexist, determination is made by combining both the congestion state and the transmission error state, and the cause is determined mainly by the wired network or the wireless network. Different distribution control depending on the location of the data, the data distribution can be performed appropriately, the effect of preventing unnecessary loss in the wired network to maintain the number of distributions, and the effect of preventing the data loss by reducing the number of retransmissions in the wireless network. is there.

[Brief description of the drawings]

FIG. 1 is a diagram showing a system configuration according to Embodiments 1 and 2 of the present invention.

FIG. 2 is a diagram showing an internal configuration of a distribution server according to the first embodiment.

FIG. 3 is a diagram showing an operation flow of a distribution server according to the first embodiment.

FIG. 4 is a diagram showing an operation flow of a distribution server according to Embodiment 2 of the present invention.

FIG. 5 is a diagram showing another operation flow according to the second embodiment of the present invention.

FIG. 6 is a diagram illustrating an example of an RTCP packet according to Embodiment 2 of the present invention.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 distribution server, 2 wired (network) network, 4 base station device, 5 gateway, 6 wireless network, 11 network interface unit, 12 data receiving unit, 13
Reception status detection unit, 14 congestion determination unit, 15 transmission error determination unit, 16 rate control unit, 17 data transmission unit, 20
Distribution number control unit, 21 session priority determination unit, 25
RTCP original extension part, 31, 32, 33 mobile terminal, S31 step for obtaining delay time, packet loss rate, transmission error rate, S33 congestion determination step, S34
Transmission error determination step, S35 packet distribution rate reduction step, S35 'packet length reduction step, S3
5 ”packet distribution number reduction step, S41 transmission error rate acquisition step, S42 priority determination step, S44
Comparing with a threshold value, S44, determining that a transmission error has occurred, S45 determining that no transmission error has occurred, S46 location information obtaining step, S47.
Error rate adding step, S48 threshold value and comparing step, S
49 a step of determining that a transmission error has occurred.

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Kazuma Fukuda 2-3-2 Marunouchi, Chiyoda-ku, Tokyo F-term within Mitsubishi Electric Corporation (reference) 5K030 HB17 HB21 HD03 JL01 MB02 MB05 MB11 5K033 BA15 CB06 CB17 CC01 DA05 DA17

Claims (8)

[Claims] In a configuration of a distribution apparatus that distributes a packet to a terminal through a wired network and a wireless network, a determination of a congestion state obtained from a packet loss rate including a delay and a determination of a transmission error state obtained from a transmission error rate are performed. Based on both the determination and the determination, if it is determined that the packet is in a congested state and there is no transmission error, the distribution rate of the packet is reduced, and if it is determined that the packet is in a congested state and it is also a transmission error, the packet is changed to a predetermined distribution method. A wired / wireless mixed network data distribution device including a rate control unit. 2. The wired wireless communication according to claim 1, wherein when the rate control unit determines that the packet is in a congestion state and is also a transmission error, the packet length is shortened and distributed thereafter. Mixed network data distribution device. 3. A packet priority is set for the packet, and a distribution number control means is provided in place of the rate control unit. When the distribution number control means determines that the packet is in a congestion state and is not in a transmission error state, the packet number is determined. 2. The wired / wireless mixed network data distribution apparatus according to claim 1, wherein the number of distributions of the low priority packets is reduced. 4. A packet is set with a priority and a location to which a terminal belongs. The transmission error rate is combined with the priority and location information to determine a transmission error. 4. The wired / wireless mixed network data distribution device according to claim 2, wherein the data length is shortened. 5. A distribution system for distributing a packet to a terminal through a wired network and a wireless network, wherein a step of obtaining a packet distribution delay time, a packet loss rate, and a transmission error rate is performed. A transmission error determination step of determining a transmission error occurrence state from the transmission error rate; and a congestion determination in the congestion determination step, and a packet delivery rate in a case where the transmission error step determines that there is no error. And a wired / wireless mixed network data distribution method. 6. The wired wireless communication method according to claim 5, further comprising the step of shortening the length of the packet and distributing the packet when it is determined that congestion has occurred in the congestion determination step and an error has occurred in the transmission error determination step. Mixed network data distribution method. 7. A priority is set for a packet, and when it is determined in the congestion determination step that there is no congestion and in the transmission error determination step that no error has occurred, the packet delivery rate is reduced to lower the packet delivery rate. 6. The wired / wireless mixed network data distribution method according to claim 5, further comprising the step of reducing the number of distributions. 8. A packet is set with a priority and a location to which a terminal belongs, and the transmission error rate is combined with the priority and the location information to determine a transmission error. 6. The method according to claim 5, further comprising the step of: