JP3479841B2 - Uplink modulation agile method and uplink modulation agile circuit for communication device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an upstream modulation agile method and an upstream modulation agile circuit in a communication device such as a center communication control device of a CATV communication system.

[0002]

2. Description of the Related Art In recent years, a transmission line of a CATV (cable television) system is connected to a terminal device arranged at home, and downlink communication from a center communication control device to a terminal device and center communication control from each terminal device are performed. High-speed communication using a transmission line has attracted attention in two-way communication including upstream communication to a device. In order to provide communication services, it is necessary to improve communication quality. However, upstream combined noise on the CATV transmission line often interferes with upstream communication (reception), and the communication may be interrupted due to the influence of the noise. This upstream combined noise is a noise that is generated in the vicinity of the terminal device and accumulated in the vicinity of the center communication control device, and is generally unspecified.
There are various types of terminal devices, and it is difficult to remove them. Such a problem is inherent not only in the CATV system but also in other communication devices that perform two-way communication.

[0003]

As a method for preventing communication interference due to upstream combined noise and maintaining a good communication state,
For example, the frequency agile method described in Japanese Patent Laid-Open No. 2000-69443 is known.

In this frequency agile method, upstream ingress noise is monitored, and if it is detected that the upstream ingress noise deteriorates the communication quality in the upstream frequency band, the upstream frequency band is quickly changed to a noise-free band. (Agile)
It is a method to do. However, this frequency agile method causes a problem when there is no changeable frequency band. Such a problem arises not only in the CATV system but also in other communication systems that perform two-way communication.
Inherent.

The present invention has been made in view of the above circumstances, and in a communication system such as a CATV system, a communication device which prevents disconnection of upstream communication due to upstream combined noise and maintains a good communication state. The purpose is to provide.

[0006]

In order to solve the above-mentioned problems, the first invention of the present invention provides a communication device as follows.
Takes the up modulation agile method. That is, terminal equipment
Transmits upstream data that is modulated using a predetermined modulation method
And the terminal device via the transmission path.
In the communication device for transmitting downlink data to the
Noise level of the signal given from the terminal device through the path.
If the noise level exceeds a predetermined value,
An instruction to stop the transmission of the upstream data is transmitted via the transmission line.
And a first stop process for providing the terminal device with the first stop process.
The terminal device stops transmission of the uplink data by the stop processing.
While the terminal is stopped, the terminal device
The modulation method to be used is changed from the predetermined modulation method to another modulation method.
To modulate to and send the stopped upstream data
And the instructions to restart the
A modulation method change process for transmitting to the terminal device via a path,
The terminal device uses the modified modulation method to transmit the uplink data.
When the period for modulating and transmitting the data exceeds the specified time
In addition, stop transmission of the uplink data through the transmission line to the end.
Second stop processing for instructing the end device, and the second stop processing
Reason, the terminal device stops transmitting the uplink data.
Used by the terminal device for the uplink data during
And stop to change the specified modulation method back to the specified modulation method
Create an instruction to restart the transmission of upstream data
Then, these instructions are sent to the terminal device via the transmission line.
The modulation scheme restoration process to be transmitted is executed.

[0007] By took method such as this, during normal operation, performs a predetermined modulation scheme terminal apparatus with respect to the uplink data will be transmitted to the communication device, the noise of the received signal in the communication device Measure the level. As a result of the measurement,
When the noise level exceeds the predetermined value, the terminal device is instructed to change the modulation method used by the terminal device to modulate the uplink data. Therefore, predetermined
Uplink data modulated by a modulation method different from that of
Communication is performed, and after a certain period of time
, The original modulation method is restored and the upstream data is transmitted.
Be done. Therefore, upstream data communication is not interrupted. Also,
By the first stop processing, the terminal device transmits the uplink data.
And change the modulation method used by the terminal device during this period.
Is performed, and the specified modulation method is changed to another modulation method.
To restart the transmission of upstream data that has been stopped.
The indication is transmitted to the terminal device. And the terminal device changed
The period during which the uplink data is modulated and transmitted by the
When the time exceeds a predetermined time, by the second stop processing,
The terminal device stops transmitting uplink data and modulates during that period
Instructed to return the system to the original specified modulation system and stopped.
The instruction to restart the transmission of uplink data is sent to the terminal device.
Believed Therefore, with the transmission of upstream data stopped
Since the modulation method is changed and the predetermined modulation method is restored,
It is also possible to prevent deterioration of upstream data.

[0008]

[0009]

In a second invention, the communication device of the first invention
In the up-modulation agile method of, the following method is taken. That is, in the modulation method changing process, one modulation method is selected from a plurality of modulation methods, and the noise level of the signal when the terminal device modulates the uplink data using the selected modulation method is set. The investigation process is repeated by changing the selection of the modulation method until the noise level becomes less than the predetermined value, and the modulation method in which the noise level becomes less than the predetermined value is used when the terminal device transmits the uplink data. The point is to set it as a modulation method. By adopting such a method, the most suitable modulation method that can be used is selected from a plurality of modulation methods, and the upstream data is modulated using the selected modulation method.

According to a third aspect of the invention,
In the uplink modulation agile method for a communication device, the gist of the communication device is to form a wired television system together with a plurality of the terminal devices. When such a method is adopted, there is a high possibility that upstream data transmitted from the terminal device can be prevented from being interrupted by ingress noise, which is a problem in a CATV system that provides services to a plurality of terminal devices.

According to a fourth aspect of the invention, the upstream modulation agile circuit has the following configuration. That is, it is a circuit provided in a communication device that receives uplink data modulated by a terminal device using a predetermined modulation method via a transmission path and transmits downlink data to the terminal device via the transmission path. Te is connected to the transmission line, measures a receiving means for receiving the signals transmitted, demodulating means for demodulating an output signal of said receiving means, the noise level of the output signal of the previous SL receiving means from the terminal device Noise measuring means, signal control means for reading the noise level measured by the noise measuring means at a predetermined timing, and outputting a judgment signal indicating whether or not the noise level exceeds a predetermined value, and the signal control means for the judgment signal. When the terminal device detects that the noise level in the signal transmitted using the predetermined modulation method exceeds a predetermined value, the terminal device refers to the determination signal and outputs the predetermined signal to the predetermined level. A modulation method selecting unit that selects a changeable modulation method that can be used instead of the modulation method, and selects a predetermined modulation method when a predetermined time has elapsed after selecting the change modulation method, and the modulation method. Message creating means for creating messages respectively corresponding to the changing modulation scheme and the predetermined modulation scheme selected by the selecting means, and control data transmitting means for sequentially transmitting the messages to the terminal device via the transmission path. The point is to have and.

By adopting such a configuration, during the normal operation in which the terminal device modulates and transmits the upstream data by the predetermined modulation method, the upstream data is received by the receiving means via the transmission path and the demodulating means. Demodulated by. Here, the noise level in the output signal of the receiving unit is measured by the noise measuring unit, and the signal control unit outputs the determination signal corresponding to the noise level. When the noise level in the signal transmitted by the terminal device using the predetermined modulation method exceeds a predetermined value, a modulation method for changing, which is an alternative to the predetermined modulation method, is selected by the modulation method selecting means, and the selected change is performed. A message corresponding to the modulation scheme for use is created by the message creating means. This message is transmitted from the control data transmitting means to the terminal device, and the terminal device uses the changing modulation scheme.

Then, when the period during which the terminal device is modulating the upstream data using the changing modulation method becomes a certain time,
The modulation method selection means selects a predetermined modulation method, and a message corresponding to the predetermined modulation method is created by the message creation means. This message is transmitted to the terminal device by the control data transmitting means, and the terminal device again uses the predetermined modulation method.

A fifth aspect of the present invention is the uplink modulation agile circuit of the fourth aspect of the invention, wherein the message creating means performs processing for the modulation scheme selecting means to select the changing modulation scheme based on the determination signal. A function of detecting and generating a stop message for stopping the transmission of the upstream data to the terminal device and notifying the terminal device via the control data transmitting means and the transmission path before the detection; When creating a message corresponding to a modulation method, a function of creating a restart message for restarting the transmission of the uplink data in the terminal device and notifying the terminal device via the control data transmission means and the transmission path, When a certain period of time has passed since the modulation method selection means selected the changing modulation method, the stop message is generated to generate the control data. Data transmission means and the function of notifying the terminal device via the transmission path, and when creating a message corresponding to the predetermined modulation method, the restart message is created to create the control data transmission means and the transmission path. The gist is to have a function of notifying to the terminal device via the.

By adopting such a configuration, when the modulation method selection means performs the process of selecting the changing modulation method based on the determination signal, the transmission of the uplink data to the terminal device is stopped before the start. A stop message is generated and sent to the terminal device. Further, when the selection of the changing modulation scheme is completed, a message corresponding to the changing modulation scheme and a restart message for starting transmission of uplink data are created and given to the terminal device. As a result, the uplink data is not transmitted during the period when the changing modulation scheme is selected. Similarly, the uplink data is not transmitted even during the period in which the modulation scheme used by the terminal device is switched from the modification modulation scheme to the predetermined modulation scheme.

According to a sixth aspect of the invention, the upstream modulation agile circuit of the fourth or fifth aspect of the invention has the following configuration. That is, it is determined that the predetermined modulation scheme used by the terminal device is inappropriate based on a modulation table storing a plurality of pieces of information about the changing modulation scheme and information indicating the predetermined modulation scheme and the determination signal. At this time, the changing modulation schemes stored in the modulation table are sequentially scanned, and the changing modulation scheme in which the noise level of the output signal of the receiving means does not exceed a predetermined value is subsequently used by the terminal device. The pointer control circuit includes a pointer control circuit selected as a modulation method, and a recovery timer that measures a fixed time after the pointer control circuit selects the modification modulation method, and the pointer control circuit includes the recovery timer. Is configured to select the predetermined modulation method as a modulation method to be used thereafter by the terminal device when the predetermined time is measured.

By adopting such a configuration,
When it is determined by the determination signal that the predetermined modulation method used by the terminal device is inappropriate, the plurality of changing modulation methods stored in the modulation table are sequentially scanned, and the noise level of the output signal of the receiving means is changed. A changing modulation method that does not exceed a predetermined value is selected. Further, the pointer control circuit selects a predetermined modulation method when the recovery timer measures a certain time. According to a seventh aspect of the present invention, the upstream modulation agile circuit according to any one of the fourth to sixth aspects has the following configuration. That is, the signal control means includes a first timer that generates a first timing signal at a constant interval, a second timer that generates a second timing signal at an interval shorter than the first timer, and While the terminal device is modulating the upstream data by the predetermined modulation method, the noise level measured by the noise measuring means is read in synchronization with the first timing signal, and the modulation method selecting means reads the noise level. During the period for selecting the modulation method for change, the noise level monitoring control circuit that reads the noise level in synchronization with the second timing signal is compared with the noise level read by the noise level monitoring control circuit and the threshold value. And a threshold value judgment circuit for outputting the judgment signal.

By adopting such a configuration, the noise level monitoring control circuit measures the noise in synchronization with the first timing signal while the terminal device is modulating the upstream data by the predetermined modulation method. The noise level measured by the means is read, and the noise level is read and output in synchronization with the second timing signal during the period when the modulation method selection means selects the modulation scheme for change. Therefore, the noise level is measured at finer intervals than during normal operation until the change modulation method is selected.

[0020]

1 is a block diagram showing the configuration of a modulation agile circuit according to an embodiment of the present invention. This modulation agile circuit configures a transmission / reception unit of a communication control device installed in a CATV communication center, monitors a noise level in an operating upstream frequency band, and prepares in advance when it is determined that the noise level cannot be operated. It has a function of changing to the above-mentioned change modulation system. The transceiver unit of the communication control device
An upstream tuner circuit 10 which is a receiving means for receiving a signal from a terminal device (not shown) via a transmission path, an upstream data demodulation circuit 20 which is a demodulating means connected to the upstream tuner circuit 10, and transmits data to the terminal device. And a downlink data transmission modulation circuit 30 for The modulation agile circuit includes the upstream tuner circuit 10 to the downstream data transmission modulation circuit 30, and an upstream noise level measuring circuit 40 which is a noise measuring means connected to the output terminal of the upstream tuner circuit 10.
And a modulation agile determination circuit 50 which is a signal control means.
, A terminal control message generation circuit 60 which is a message creation means, and a modulation selection circuit 70 which is a modulation method selection means.
And a downlink data multiplexing circuit 80 which is a control data transmitting means.
It consists of and.

A terminal control message generation circuit 60 and a modulation selection circuit 70 are connected to the output side of the conversion agile determination circuit 50. The downlink data multiplexing circuit 80 is connected to the output side of the terminal control message generation circuit 60, and the downlink data transmission modulation circuit 30 is connected to the output side of the downlink data multiplexing circuit 80. The output terminal of the modulation selection circuit 70 is connected to the modulation agile circuit 50, the terminal control message generation circuit 60, and the upstream data demodulation circuit 20. The functions and configuration examples of the circuits 40 to 80 are shown below.
The upstream noise level measurement circuit 40 utilizes the interval between the upstream burst signals from the terminal device to output the output signal S of the upstream tuner circuit 10 when the upstream data signal SDu does not exist.
It has the function of measuring the noise level in 10 frequency bands. FIG. 2 shows a conversion agile decision circuit 50 shown in FIG.
3 is a block diagram showing a configuration example of FIG.

The conversion agile judging circuit 50 judges whether or not the noise level S40 output by the upstream noise level measuring circuit 40 exceeds a predetermined value and outputs a judgment signal S50. The noise level value monitoring control Circuit 51, first timer 52, second timer 53, and timer 54
And a threshold decision circuit 55. The noise level value monitoring control circuit 51 supplies a read signal (not shown) to the upstream noise level measuring circuit 40 at a predetermined timing, fetches the noise level measurement result S40, and uses the fetched measured value S40 as the threshold value judgment circuit 55. Output to. The threshold determination circuit 55 uses the acquired noise level as
Compared with a threshold value set in advance, if it is larger than the threshold value, it is determined to be excessive, and if it is smaller than the threshold value, it is determined to be excessively small, and the determination signal S50 is set to the noise level value. Monitor control circuit 51, terminal control message generation circuit 6
0 or output to the modulation selection circuit 70.

The noise level value monitoring control circuit 51 has a timing signal S52 output from the timer 52 in a normal operation state.
While the noise level measurement result S40 is read at the timing synchronized with, the measurement result S40 is read at the timing synchronized with the timing signals S54 and S55 output from the timer 53 or the timer 54 while the modulation method is being changed. Specifically, the noise level value monitoring control circuit 51 determines that the determination signal S5
When 0 indicates an excessive value, according to the timing of the timer 53, when a return signal S74 indicating to return to the original modulation method is given from the modulation selection circuit 70, the noise level measurement result follows the timing of the timer 54. The reading of S40 is started. The interval of the timing signal S53 output by the timer 53 is shorter than the interval of the timing signal S52 output by the timer 52, and the interval of the timing signal S54 output by the timer 54 is the timing signal S52.
Is set longer than the interval. The terminal control message generation circuit 60 of FIG. 1 generates a message instructing to stop transmission of uplink data according to the determination signal S50 supplied from the modulation agile determination circuit 50, and the modulation parameter given from the modulation selection circuit 70. A function of generating a message indicating a modulation method for modulating the uplink data according to the number S72 and a message instructing restart of the transmission of the uplink data and outputting these to the downlink data multiplexing circuit 80 as the control signal S60 is provided. have.

FIG. 3 is a block diagram showing a configuration example of the modulation selection circuit 70 in FIG. The modulation selection circuit 70 is composed of a pointer control circuit 71, a modulation table 72 composed of a memory, a modulation setting circuit 73 and a recovery timer 74, and the original modulation method used in the terminal device is changed to another modulation method. The function to select the modulation method to change to the method,
It has a function of returning to the original modulation method at a predetermined timing. The pointer control circuit 71 uses the first address value of the modulation table 72 as an initial value, and supplies the determination signal S
When 50 indicates an excessive value, it has a function of adding 1 to the current address value and outputting it to the modulation table 72. Also,
The pointer control circuit 70 also has a function of determining whether the address value given to the modulation table 72 is the maximum address value.

The modulation table 72 stores a plurality of modulation parameter numbers for indicating a plurality of modulation methods in association with addresses, and the modulation parameter number S72 corresponding to the output address value of the pointer control circuit 71 is set in the modulation setting circuit 73.
To the terminal control message generation circuit 60. The modulation setting circuit 73 converts the supplied modulation parameter number S72 into a modulation setting signal S73, and the uplink data demodulation circuit 20
Output to. The timer 74 sets the operation time from the restart of the operation after the change of the modulation method to the return to the original modulation method. When the set time elapses, the recovery timing signal S74 is modulated. It has a function of supplying to the agile determination circuit 50 and the pointer control circuit 71.

Note that the modulation method is specifically changed by the QPS.
In addition to system changes such as the K (Quadrature Phase Shift Keying) system and the QAM (Quadrature Amplitude Modulation) system, changes in the modulation speed are also included. FIG. 4 is a flowchart showing an uplink modulation agile method of a communication device performed by the uplink modulation agile circuit of FIG. The modulation agile method of the communication device will be described with reference to FIG. During normal operation, the terminal device modulates the upstream data SDu by using a predetermined modulation method set in advance, and transmits the upstream data SDu to the communication control device side via the transmission line L. The upstream tuner circuit 10 of the receiving unit of the communication control device selects the frequency of the upstream data SDu modulated from the terminal device, and outputs the output signal S10 to the upstream data demodulation circuit 20 and the upstream noise level measurement circuit 40. The upstream data noise level measurement circuit 40 measures the noise level in the signal S10 and outputs the measurement result S40. The upstream data demodulation circuit 20 demodulates the output signal S10 of the upstream tuner circuit 10 and outputs upstream data S20. The demodulation processing performed by the upstream data demodulation circuit 20 is set according to the modulation setting signal S73 supplied from the modulation setting circuit 73, and corresponds to the modulation processing performed by the terminal device.

In step ST1, the noise level value monitoring control circuit 51 in the modulation agile determination circuit 50 uses the timing signal S5 of the timer 52 used during normal operation.
The noise level measurement result S40 is read in synchronization with 2.
It is sent to the threshold value judgment circuit 55. In step ST2, the threshold determination circuit 55 determines whether or not the measurement result S40 is larger than the threshold, and outputs the determination signal S50. At this time, when the noise level measurement result S40 is smaller than the threshold value (NO), the noise level value monitoring control circuit 51 continues to read the noise level measurement result S40 at the timing set by the timer 52. repeat. When the measured value S40 is larger than the threshold value (YES), the threshold value determination circuit 55 supplies the terminal control message generation circuit 60 and the pointer control circuit 71 with the determination signal S50 indicating an excess.

In step ST3, the terminal control message generating circuit 60 generates a message indicating stop of uplink transmission to the corresponding terminal device, and outputs this to the downlink data multiplexing circuit 80 as an output signal S60. The downlink data multiplexing circuit 80 transfers the signal S60 to the downlink data SDd.
To multiplex. The downlink data transmission modulation circuit 30 modulates the output signal S80 of the downlink multiplexing circuit 80 and transmits it to the terminal device. The above steps ST1 to ST3 are the first stop processing, and when the noise level is high, the terminal device stops the transmission. In step ST4 after step ST3, the pointer control circuit 71 adds 1 to the current address value (pointer value) of the modulation table 72 and outputs it to the modulation table 72. Also, step ST
In 5, the pointer control circuit 71 determines whether the pointer value is the maximum address value. If the pointer value is the maximum address value (YES), step ST1 described later is performed.
Go to 6. When the pointer value is not the maximum address value (NO), in step ST6, the modulation table 72 selects the modulation method corresponding to the pointer value, and outputs the modulation parameter number indicating the selected modulation method as the output signal S72. To the modulation setting circuit 73 and the terminal control message generation circuit 60.

In step ST7, the modulation setting circuit 7
3 converts the supplied modulation parameter number S72 into a modulation setting signal S73 and outputs it to the upstream data demodulation circuit 20. The upstream data demodulation circuit 20 changes the setting of the modulation method. That is, the demodulation method for demodulating the upstream data is changed. In addition, the terminal control message generation circuit 60
The message corresponding to the modulation parameter number is sent to the signal S60.
And is transmitted to the terminal device via the downlink data multiplexing circuit 80 and the downlink data transmission modulation circuit 30. As a result, the terminal device switches the modulation method on a trial basis. In step ST8, the noise level value monitoring control circuit 51 in the modulation agile determination circuit 50 reads the noise level measurement result S40 at the timing set by the timing signal S53 output from the timer 53, and in step ST9, the threshold value is set. The determination circuit 55 determines whether the measurement result S40 is larger than the threshold value. When the measurement result S40 is larger than the threshold value in step S9 (NO), the process returns to step ST4, the next modulation method stored in the modulation table 72 is selected, and the threshold value determination result becomes too small. Repeat noise level investigation up to. By repeating steps ST4 to ST9 in this manner, the modulation table 72 is scanned.

If the measurement result S40 is smaller than the threshold value (YES) in step S9, the noise level value monitoring control circuit 51 causes the measurement result S4 to be measured at the timing of the timer 53.
0 is read, and in step ST10, the threshold determination circuit 55 repeats the operation of determining whether or not the measurement result S40 is larger than the threshold a predetermined number of times. When the noise level value is stable and the noise level investigation is completed (YES)
In step ST11, the terminal control message circuit 11 creates a message corresponding to the parameter number indicating the changing modulation method, assuming that the changing modulation method used by the terminal device instead of the predetermined modulation method is selected. Then, this is output to the downlink data multiplexing circuit 80 as the output signal S60. The downlink data multiplexing circuit 80 multiplexes the signal S60 with the downlink data SDd. Downlink data transmission modulation circuit 3
0 modulates the output signal S80 of the downlink multiplexing circuit 80 and transmits it to the terminal device. Further, the terminal control message circuit 1
In step ST12, 1 generates a message indicating the resumption of uplink transmission, and outputs it as the signal S60 to the downlink data multiplexing circuit 80. The downlink data multiplexing circuit 80 multiplexes the signal S60 with the downlink data SDd. The downlink data transmission modulation circuit 30 modulates the output signal S80 of the downlink data multiplexing circuit 80 and transmits it to the terminal device.

Steps ST4 to ST at this time
12 is a modulation method change process,
By ST12, the change of the uplink modulation scheme and the resumption of the uplink transmission are notified to the corresponding terminal device.
The terminal device changes the modulation scheme for the uplink data and restarts transmission of the uplink data SDu modulated by the changed modulation scheme.

After the operation is restarted, after the time set by the timer 54 has passed (step ST13), the process is returned to step ST1. After the operation is restarted, if the time set in the timer 74 of the modulation selection circuit 70 has elapsed (step S14), the terminal control message generation circuit 60 stops the uplink transmission to the corresponding terminal device in step ST15. The message shown in FIG.
Output to 0. The downlink data multiplexing circuit 80 outputs the output signal S60 of the terminal control message generation circuit 60 to the downlink data S
Multiplex into Dd. The downlink data transmission modulation circuit 30 modulates the output signal S80 of the downlink multiplexing circuit 80 and transmits it to the terminal device. The steps ST14 and ST15 are the second stop processing, whereby the terminal device stops the transmission of the uplink data.

In step ST16, the pointer control circuit 71 sets the pointer value to the initial value. As a result, the modulation table 72 selects the original modulation method before changing the modulation method in step ST17. Next, when the process of step S17 ends, the process returns to step ST7, and if the noise level is smaller than the threshold value and stable, the operation is resumed by the original predetermined modulation method.

In this embodiment as described above, the following effects can be obtained. ○ When there is ingress noise etc. when transmitting uplink data from the terminal device, the modulation method is changed instead of changing the transmission frequency of the terminal device, so even if there is no frequency to change, the uplink data It is possible to prevent the transmission from being interrupted. ○ When changing the modulation method, stop the transmission of uplink data to the corresponding terminal device, change the modulation method each time, investigate the noise level in the absence of uplink data, and in order Since it searches for an operable modulation method,
During the search, the upstream data from the terminal device does not reach the communication control device side. Therefore, the modulation system search can be executed in a short time. Further, since the modulation scheme used by the terminal device is changed in the state where the transmission of the uplink data is stopped, the uplink data is not deteriorated.

When investigating the noise level, communication disconnection due to authentication of the terminal device does not occur. Therefore, communication becomes possible immediately after the operation is resumed. ○ It is not necessary to have another receiving circuit for measuring the noise level, unnecessary hardware is unnecessary, and the hardware scale can be small. The present invention is not limited to the above embodiment, and various modifications can be made. The following are examples of such modifications.

(1) In the above embodiment, the upstream modulation agile circuit provided in the communication control device of the CATV system connected to the plurality of terminal devices via the transmission line L is described as an example. It is also possible to apply to other communication devices connected to the terminal device. For example, 1
It can also be applied to a communication device that communicates only with individual terminal devices. Further, the present invention can be applied to the case of configuring a system other than the CATV system, and by changing the modulation method, the same effect as that of the above embodiment can be obtained. (2) In the above embodiment, the threshold judgment circuit 55 judges the magnitude relationship between the threshold and the noise level, but a circuit for counting the number of times that the noise level becomes larger than the threshold is further added. A count determination condition for determining inoperability based on the count value may be added.

(3) The modulation agile judgment circuit 50, the terminal control message generation circuit 60 and the modulation selection circuit 70 are
It may be realized by means of software by a CPU instead of the circuit configuration by hardware. (4) The upstream noise level measurement circuit 40 may measure the noise level from the output signal of the upstream data demodulation circuit 20.

[0038]

As described in detail above, according to the first aspect of the invention, the modulation method is changed even if noise enters the transmission line, so that the terminal device can communicate even when there is no frequency to be changed. It is possible to secure communication of upstream data transmitted to the device.
Further, since the modulation method change processing is performed after the uplink data transmission is stopped in the first stop processing, and the modulation method restoration processing is performed after the uplink data transmission is stopped in the second stop processing, It is not damaged. According to the second aspect of the present invention, a modulation method that replaces a predetermined modulation method is selected from a plurality of modulation methods, so that a noise-resistant modulation method can be selected and stable communication quality can be maintained.

According to the third invention, since the CATV system is configured by the communication device and the terminal device, it is easy to maintain the upstream communication in the CATV system even if there is a stream noise. According to the fourth invention, the receiving means, the demodulating means, the noise measuring means for measuring the noise level, the signal control means for outputting the discrimination signal according to the noise level, and the modulation method for selecting the changing modulation method. Since the up-modulation agile circuit is configured by using the selection means, the message creation means, and the control data transmission means, the modulation method is changed even if noise enters the transmission line. However, the communication of the uplink data transmitted from the terminal device to the communication device can be secured.

According to the fifth invention, the message creating means creates the stop message and the restart message, so that these messages are given to the terminal device. Therefore, the modulation scheme of the terminal device can be changed while the transmission is stopped. Therefore, the upstream data will not be lost by the modulation method changing process. Furthermore, the modulation method can be promptly selected. According to the sixth aspect of the invention, since the modulation selection means is configured by using the modulation table, the pointer control circuit, and the return timer, the changed modulation method can be selected by scanning the change table.

According to the seventh invention, since the signal control means is constituted by the first and second timers, the noise level monitoring control circuit, and the threshold value judging circuit, the period for selecting the changing modulation method The second timing signal having a shorter interval than the first timing signal output from the second timer,
Since the noise level monitoring control circuit reads the noise level, the speed of selecting the modulation method can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a modulation agile circuit according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a modulation agile determination circuit in FIG.

3 is a block diagram showing a configuration of a modulation selection circuit in FIG.

FIG. 4 is a flowchart showing a flow of an uplink modulation agile method of a communication device.

[Explanation of symbols]

10 ... Upstream tuner circuit 20 as receiving means ... Upstream data demodulating circuit 30 as demodulating means ... Downstream data transmission modulation circuit 40 ... Upstream noise level measuring circuit 50 as noise measuring means ... Modulation agile determination circuit 51 as signal controlling means ... noise level value monitoring control circuit 52 ... first timer 53 ... second timer 55 ... threshold value judgment circuit 60 ... terminal control message generation circuit 70 as message creation means ... modulation selection circuit 71 as modulation method selection means ... pointer control circuit 72 ... modulation table 74 ... recovery timer 80 ... downlink data multiplexing circuit as control data transmitting means

Claims (7)

(57) [Claims] 1. A communication device in which a terminal device receives uplink data modulated using a predetermined modulation method via a transmission line and transmits downlink data to the terminal device via the transmission line, wherein the transmission is performed. If the noise level of the signal given from the terminal device through the path is measured and the noise level exceeds a predetermined value,
In the case of the transmission, an instruction to stop the transmission of the uplink data is transmitted.
A first stop process to be given to the terminal device via a road;
While the terminal device is not transmitting data, the terminal device
The modulation method used for transmitting the data from the predetermined modulation method
An instruction to change to another modulation method and the upstream that was stopped
Create instructions and instructions to resume sending data and
Method for transmitting an indication to the terminal device via the transmission path
The changing process and the terminal device using the changed modulation method
When the period for modulating and transmitting the data exceeds the specified time
In addition, stop transmission of the uplink data through the transmission line to the end.
A second stop process for instructing the end device, and the terminal device causes the uplink data to be transmitted by the second stop process.
While the terminal device is not transmitting data, the terminal device
Return the modulation method used for the
To restart the transmission of upstream data that had been stopped.
And create these instructions via the transmission line.
The modulation system restoration process transmitted to the terminal device is performed.
Up-modulation agile method for communication device characterized by
Law. 2. In the modulation method change processing, one modulation method is selected from a plurality of modulation methods, and the signal of the signal when the terminal device modulates the uplink data using the selected modulation method. The process of investigating the noise level is repeated by changing the selection of the modulation method until the noise level becomes less than the predetermined value, and the terminal device transmits the uplink data in the modulation method in which the noise level becomes less than the predetermined value. up-modulating agile method for a communication apparatus according to claim 1, wherein the set as the modulation scheme used when. Wherein the communication device is up-modulating agile method for a communication apparatus according to claim 1 or 2, characterized in that it constitutes a cable television system I the plurality of terminal devices coupled with. 4. A communication device for receiving uplink data modulated by a terminal device using a predetermined modulation method via a transmission path and transmitting downlink data to the terminal device via the transmission path. A circuit, which is connected to the transmission line, receives the signal transmitted from the terminal device, demodulates the demodulation of the output signal of the receiving means, and the noise level of the output signal of the receiving means. Noise measuring means for measuring, signal control means for reading the noise level measured by the noise measuring means at a predetermined timing and outputting a judgment signal indicating whether or not the noise level exceeds a predetermined value, the judgment signal When the terminal device detects that the noise level of the signal transmitted using the predetermined modulation method exceeds a predetermined value, the terminal device is referred to while referring to the determination signal. And a modulation method selection means for selecting a changeable modulation method that can be used instead of the predetermined modulation method, and selecting the predetermined modulation method again when a predetermined time has elapsed after selecting the change modulation method. Message creating means for creating and outputting a message respectively indicating the changing modulation scheme and the predetermined modulation scheme selected by the modulation scheme selecting means for changing the modulation scheme used by the terminal device, An upstream modulation agile circuit comprising: a control data transmitting unit for inputting a message created by the message creating unit and sequentially sending the message to the terminal device via the transmission path. 5. The message creating means detects, based on the determination signal, that the modulation method selecting means performs a process of selecting the changing modulation method, and the terminal device is provided with the A function of creating a stop message for stopping the transmission of uplink data and notifying the terminal device via the control data transmitting means and the transmission path, and the terminal device when creating the message indicating the modulation scheme for change. And a function of creating a restart message for restarting the transmission of the uplink data and outputting it to the control data transmitting means together with a message indicating the changing modulation method, and the modulation method selecting means selecting the changing modulation method. And a predetermined modulation method for generating the stop message and outputting the stop message to the control data transmitting means when a predetermined time has passed from 5. The uplink modulation according to claim 4, further comprising a function of creating the restart message when the message indicating the expression is created and outputting the restart message together with the message indicating the predetermined modulation method to the control data transmitting means. Agile circuit. 6. The modulation method selecting means stores a plurality of pieces of information on the changing modulation method and information indicating the predetermined modulation method, and the judgment signal to be used by the terminal device. When it is determined that the predetermined modulation method is inappropriate, the change modulation methods stored in the modulation table are sequentially scanned, and the change modulation in which the noise level of the output signal of the receiving means does not exceed a predetermined value. A method is provided with a pointer control circuit that selects a method as a modulation method used by the terminal device thereafter, and a return timer that measures a fixed time after the pointer control circuit selects the change modulation method, The pointer control circuit is configured to select the predetermined modulation method as a modulation method to be subsequently used by the terminal device when the return timer measures the predetermined time. The upstream modulation agile circuit according to claim 4 or 5, wherein 7. The signal control means comprises: a first timer for generating a first timing signal at a constant interval; and a second timer for generating a second timing signal at an interval shorter than the first timer. During the period in which the terminal device is modulating the upstream data by the predetermined modulation method, the noise level measured by the noise measuring means is read in synchronization with the first timing signal, and the modulation method is selected. During the period in which the means selects the changing modulation method, the second
A noise level monitoring control circuit for reading the noise level in synchronization with the timing signal, and a threshold value judging circuit for comparing the noise level read by the noise level monitoring control circuit with a threshold value and outputting the judgment signal. 7. The structure according to claim 4, wherein
11. The up-modulation agile circuit according to any one of 1 .