JPS6314525A - Signal level adjusting device - Google Patents

Abstract

PURPOSE:To adjust a signal level difference between terminal equipments within a reference level by providing a variable attenuator to each of a reception path and a transmission path each comprising the combination of branching filters provided between a data transmission line and a data terminal equipment. CONSTITUTION:A transmission line terminal 12 is connected to a data transmission line and a data terminal 13 is connected to a data terminal equipment in a level adjusting device 11 respectively. A reception signal inputted via the terminal 12 is connected to a 1st branching device 16 via a reception signal level variable attenuator 15. A branching device 16 branches a reception signal and a transmission signal sent via the terminal 13, the reception separating path is connected to the reception separation side of a 2nd branching device 17 and the opposed transmission separation side is connected to that of the branching device 17 via a variable attenuator 18. A directional coupler 19 is connected among the branching device 17, the terminal 13 and a monitor terminal 14 so as to branch the inputted reception signal into a monitor output and a data output. The reception level monitored at the terminal 14 is adjusted into a prescribed level by the attenuator 15 and the transmission signal level sent from the terminal 13 is adjusted into a prescribed level by an attenuator 18.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a signal level that provides a terminal with an optimal signal level for detecting signal collisions when performing data transmission using a two-way CATV system. Regarding regulators.

[Prior art and its drawbacks]

As office equipment becomes more diverse and sophisticated, LAN
(Local Ar@a Network), it is thought that there will be a need for multiple information. Traditional LAN
However, the main focus was on data transmission, and it was difficult to transmit images (particularly videos). Therefore, communication systems that use CATV technology to transmit various information such as data, audio, and video are being considered.

However, since the main purpose of this CATV system is to transmit television signals, the permissible signal level at subscriber terminals is 60 to 85 dBμ.

Therefore, depending on the installation location of the subscriber terminal, the difference in signal level can be as much as 25 dB at most.

On the other hand, using the CATV system, we can establish an international standard LAN.
The access method is C8MA/CD (Carrier
SenseMultiple Access wit
In order to perform data communication using Co11ision Detection), the level difference between the received signals of the signals from any data terminal at each terminal must be, for example, 6 dB.
It must be within the range.

That is, in C3MA/CD, detection of collisions between terminals (two or more data terminals transmitting data at the same time) is a very important function. However, if the level difference between the collision signals is 6 dB or more, the weaker signal is ignored, and even if a signal collision occurs, it cannot be detected. Therefore, in order to use the CATV system for C8MA/CD data communication, it is essential to adjust the level of the transmission signal.

Therefore, the following signal level adjustment method has been considered. First, a reference level signal is sent from the frequency converter (sometimes called a head end),
On the data terminal side that receives this pilot signal, the gain of the receiving amplifier is adjusted so that the signal level becomes an appropriate value. Then, the signal level when the test signal sent from the data terminal returns via the frequency converter is
Adjust the gain of the transmitting amplifier so that it is equal to the above reference level.

However, in such a table level adjustment method, each data terminal requires a device for adjusting the gain of the transmitting/receiving amplifier, which increases the cost of the data terminal. Furthermore, each time a data terminal moves or a new data terminal joins, it is necessary to readjust the gain of the transmitting/receiving amplifier, and there is a problem in that the network must be brought down each time this level adjustment is made.

[Purpose of the invention]

The present invention was developed in view of the above-mentioned problems. For example, even if a data terminal moves or newly joins, there is no need to bring down the network, and the difference in signal level between each data terminal can be kept within a standard level. It is an object of the present invention to provide a signal level adjuster that allows adjustment.

[Key points of the invention]

That is, the signal level adjuster according to the present invention includes first and second branching filters that separate between a data transmission path and a data terminal, and between a received signal and a transmitted signal for the data terminal; First and second variable attenuators are provided for varying the passing signal level in each of the receiving path and the transmitting path, each consisting of a combination of two branching filters, and the received signal is branched by the directional coupler to the data terminal. It is configured to adjust the monitor output.

[Embodiments of the invention]

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 shows its circuit configuration, and this signal level adjuster 11 includes a transmission line terminal 12, a data terminal 13, and a monitor terminal 14. This transmission line terminal 12 is connected to a data transmission line 2, which will be described later, and the data terminal 13 is connected to a data terminal 22, which will be described later.
2 is connected to a first branching filter 16 via a variable received signal level attenuator 15. This first demultiplexer 16 demultiplexes the received signal inputted via the transmission line terminal 12 and the transmitted signal sent out via the data terminal 13. The reception separation path of the receiver 16 is connected to the reception separation side of the second duplexer 17, and the transmission separation side thereof is connected to the second duplexer 17 via the transmission signal level variable attenuator 18.
Connect to the separate transmission path. A directional coupler 19 is connected between the second branching filter 17 and the data terminal 13 and the monitor terminal 14, and a directional coupler 19 is connected between the transmission line terminal 12 and the first
The received signal input through the second branching filter 16 and 17 is branched into a data output and a monitor output.

FIG. 2 shows a data transmission network incorporating the signal level adjuster configured as described above, in which a data transmission line 21 is connected to a head end 23, and a large number of data terminals are installed at arbitrary positions on this transmission line 2. ;j;j&, 22bl... are signal level adjusters 11a, respectively.

11b, . . . In this data transmission network, a transmission signal (upper signal) from a certain data terminal (for example, 22a) is converted into a reception signal (lower signal) by the head end 23, and each data terminal 22h,
22b, . . . Also, head end 2
3, each data terminal 2:z a + 22b r...
A reference signal generator 24 is connected which generates a reference signal of the same frequency as the lower signal, which is necessary for adjusting the received signal level at .

Next, the operation of the signal level adjuster 11 in the data transmission network having the above configuration will be explained.

First, in order to adjust the received signal level at each data terminal 22m, 22b, . . . , the reference signal generator 24
A reference signal is generated at the head end 23 and sent to the data transmission line 2 via the head end 23.

The reference signal sent to the transmission path 21 is input as a received signal to each signal level adjuster 11h, 11b+, . . . .

That is, for example, the received signal input to the signal level adjuster 11a is separated from the transmitted signal via the received signal level variable attenuator 15 and the first branching filter 16, and is further separated by the second branching filter 17 and the first branching filter 16. Data terminal 1 via directional coupler 19
3 and the monitor terminal 14. Here, the level of the received signal monitored at the monitor terminal 14 is adjusted by the variable attenuator 15 so that the received signal at the level required by the data terminal 22m is output to the data terminal 13.

Thereafter, in the same manner, the received signal level for the other data terminals 22b, . . . is adjusted by each corresponding signal level adjuster 1.
Adjust with 1b,... As a result, the signal level of the received signal sent from the head end 23 via the data transmission path 21 is determined by which data terminals 22&, 22b, . . .
are also equal.

Next, after the adjustment of the reception signal level for the data terminals 22m122b*... is completed, in order to adjust the transmission signal level for the head end 23, the reference signal generator 24 is first stopped, and for example, the reference signal generator 24 is stopped. The transmission signal from the signal level adjuster 11a is sent to the data terminal 13 of the corresponding signal level adjuster 11a.

Then, the transmission signal from the data terminal 13 is branched into the transmission separation path via the directional coupler 19 and the second branching filter 17, and then sent to the transmission signal level variable attenuator 18. The signal is sent to the data transmission line 2 via the first branching filter 16 and the attenuator 15. In this way, the transmission signal sent out to the data transmission path 21 is input to the head end 23 and is transmitted to each data terminal 22.
h, 22b, .
1h.

The received signal that has been converted and returned by the head end 23 reaches the directional coupler 19 via the same route as used for adjusting the received signal level, and is branched into a data output and a monitor output. Here, the transmission signal level variable attenuator 18 is adjusted so that the reception signal level monitored at the monitor terminal 14 becomes the same signal level as the adjustment level at the time of adjusting the reception signal level.

Thereafter, in the same manner, the transmission signal level at each of the other data terminals 22b, . . . is adjusted by each corresponding signal level adjuster 1.
1b, . . . As a result, the transmission signal input to the head end 23 can be sent to any data terminal 22.
Transmission signals from m+22b+... are also input at the same signal level.

That is, each data terminal 22a as described above.

By correcting the signal transmission characteristics between 22b, . . . , which data terminals 22 a * 22 b g .
The received signal levels are also equal, and the level difference is suppressed to within 6 dB, making it possible to reliably perform data transmission and data collision detection.

Therefore, even when a data terminal moves or newly joins, CA
It is possible to correct signal transmission characteristics throughout the TV network.

〔Effect of the invention〕

As described above, according to the present invention, between the data transmission path and the data terminal, there are provided the first and second branching filters for separating the received signal and the transmitted signal for the data terminal;
First and second variable attenuators are provided for varying the level of the passing signal in each of the receiving path and the transmitting path, each consisting of a combination of branching filters, and the receiving signal is branched to the data terminal by a directional coupler. Since the configuration is configured to adjust the output, for example, even if a data terminal moves or newly joins, there is no need to take down the transmission network, and the difference in signal level between each data terminal can be kept within the reference level:
(A signal level regulator can be provided that can be adjusted and allows collision detection between each data terminal.)

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing a signal level adjustment amount according to an embodiment of the present invention, and FIG. 2 is a diagram showing a data transmission network incorporating the signal level adjuster shown in FIG. 1. 11.11m+11b+...signal level adjuster, 12
...Transmission line terminal, J3...Data terminal, 14...
Monitor terminal, 15...Receive signal level variable attenuator, 1
6... First branching filter, 17... Second branching filter, 18
...Transmission signal level variable attenuator, 19...Directional coupler, 2 No....Data transmission line, 22m, 22b,...
- Data terminal, 23... Head end, 24... Reference signal generator. Applicant's representative Patent attorney Takehiko Suzue No. 2 Figure procedural amendment 1, case indication Patent application No. 1983-159140 2, title of invention signal level regulator 3, person making the amendment Relationship with the case Patent applicant (681) Yagi Antenna Co., Ltd. (1 idiot) 4. Agent 3-7-2 Kasumigaseki, Chiyoda-ku, Tokyo UBE Building Specification, drawings '7, Contents of amendment (1) Page 2 of the specification, No. 14 In the first line, "international standard" should be corrected to "international standard." (2) Figure 2 of the drawings will be corrected as shown in the attached sheet.

Claims (1)

[Scope of Claims] A first variable attenuator whose one end is connected to a data transmission path and whose other end is connected to a first branching filter that separates a received signal and a transmitted signal for a data terminal; The other end of the first duplexer is connected to the receiving separation side of the first branch via the second variable attenuator.
A second branching filter connected to the transmission separation side of the branching filter, and a directional coupler that branches the received signal via the second branching filter into a data output and a monitor output. A signal level adjuster characterized by: