JPH06224870A - Analog transmitter - Google Patents

Abstract

PURPOSE:To turn the generating frequency of composite second-order distortion out into an area so as not to be an obstacle to transmission by setting a minimum frequency and frequency interval of a carrier at prescribed frequencies. CONSTITUTION:The minimum (initial) frequencies of transmitting signals 1, 2 and 3 are set at (6.n+3)MHz and the frequency intervals are set at 6MHz. Therefore, the signal frequencies are turned to 3, 9, 15, 21, 27, 33, 39,... MHz, for example. Composite second-order distortion 5 and 6 to be generated at the frequency of the sum or difference of these signals is generated at 6, 12, 18, 24, 30, 36,... MHz as the integer multiple of '6' in any case. Thus, the composite second-order distortion 5 and 6 is generated at 3MHz corresponding to the boundary of four band widths required for transmitting two of transmitting signals 1, 2 and 3. Therefore, the band width + or -3MHz of the signal is not affected by this composite secondorder distortion 5 and 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a CATV (Communit
The present invention relates to an analog transmission device for transmitting a plurality of analog signals whose frequencies of carriers are equally spaced from each other through one transmission path, such as y antenna television).

[0002]

2. Description of the Related Art CATV was originally used to improve TV reception in difficult-to-view areas such as mountainous areas. A large joint antenna is used to receive radio waves from broadcasting stations.
By distributing and supplying this to each home via a cable, it becomes possible to receive a more stable TV signal than in the case of receiving a weak radio wave with a small antenna in each home in the difficult-to-view area, greatly improving the viewability. It was possible.

However, in recent years, in consideration of the fact that this cable has a sufficient information transmission capacity and can accommodate more channels than actually being broadcast, in urban areas, etc., the radio wave of a broadcasting station is simply received. In addition to re-sending to each home, it is actually practiced to broadcast original programs with its own broadcasting station and broadcast programs on more channels than existing broadcasting stations. Further, in the future, it is considered to provide a new service such as interactively exchanging information between each home and the broadcasting station.

FIG. 3 is a diagram conceptually showing such a CATV system (hereinafter referred to as a cable television).
In the figure, reference numeral 10 indicates that an electric wave from an existing broadcasting station as described above is once received by an antenna and retransmitted, or
A transmitting station that produces its own program and transmits it to each home together with the received broadcast, and 20 relays the broadcast from this transmitting station 10 to the TV receivers 60a to 60e of each home that subscribes to the cable television. It is a relay station that distributes via cables 70a to 70e. Reference numerals 40a to 40e are coaxial cables connecting the transmitting station 10 and the relay station 20, and relays 30a to 30d are provided for each predetermined distance. Further, 50 is an optical fiber cable connecting the broadcasting station 10 and the relay station 20.

As described above, a single cable is used to transmit analog signals of, for example, 40 channels from the broadcasting station 10 to the relay station 20, and conventionally, the coaxial cable 4 is used.
The signal was transmitted as an electric signal through 0a to 40e, but if the signal is transmitted through the coaxial cable, the signal is greatly attenuated.
Repeaters are required every m. On the other hand, in a new cable television, an electric signal is converted into an optical signal by a laser diode and transmitted by an optical fiber cable, so that signal attenuation is small, and for example, when transmitting a distance of 10 to 20 km, a relay is performed. A container is unnecessary, and the maintenance cost can be reduced compared to the case where a coaxial cable is used. Also, it is not affected by electrical noise.

However, in such a CATV system, since a large number of signals are transmitted by one cable, harmonic distortion occurs when signal processing is performed in a broadcasting station or a relay station, and this causes distortion of each signal. It is distributed to home TV receivers and eventually causes deterioration of the image quality.

FIG. 2 shows a composite 2 generated in a conventional device.
It is a figure showing the next distortion. In the figure, 11 is 55.2.
Transmission signal (carrier) with minimum frequency of 5 MHz, 12 is 61.25 MHz, 13 is 67.25 MHz and 6 MHz
A transmission signal (carrier) 14 output at intervals is a bandwidth required to transmit an analog video signal, and has a spread corresponding to ± 3 MHz around the frequency of the transmission signal. Reference numeral 15 is a composite second-order distortion generated at -1.25 MHz of the transmission signal 12, and 16 is + of the signal of the transmission signal 12.
It is a complex secondary distortion generated at 1.25 MHz.

For example, in the case of the NTSC system, the minimum frequency of the signal, that is, the channel with the lowest frequency is 55.2.
The frequency is 5 MHz, and the frequency is increased by 6 MHz for each channel, and a total of 42 channels of signals are transmitted. The complex second-order distortion generated at the sum or difference frequency of the signal frequencies is (6n ₁ +1.25) + (6n ₂ +1.25) = 6 (n ₁ + n ₂ ) + 2.5 = 6 · N ₁ +2 .5 or (6n ₁ +1.25) − (6n ₂ +1.25) = 6 (n ₁ −n ₂ ) = 6 · N ₂ , and the composite second-order distortion is ± of each signal frequency for the signal.
It occurs at 1.25 MHz.

[0009]

In the conventional analog transmission device, since the signal frequency of the transmission signal is set as described above, composite second-order distortion occurs at ± 1.25 MHz of the signal frequency. This is ± 3 of the bandwidth required for transmission
There is a problem in that the frequency falls within the range of MHz and becomes an obstacle to transmission.

The present invention has been made in order to solve the above problems, and provides an analog transmission device capable of driving out the composite second-order distortion from the transmission bandwidth and preventing a transmission obstacle. The purpose is to get.

[0011]

In the analog transmission device according to the present invention, the initial frequency of the carrier and its frequency interval are set so that the frequency of the generated complex second-order distortion can be driven out into a region that does not hinder the transmission. It is the one.

In the analog transmission device according to the present invention, the minimum carrier frequency is (xn + x / 2) MHz.
(X is a natural number of 6 or more, n is an integer), and the carrier frequency interval is set to x MHz.

Further, in the analog transmission apparatus according to the present invention, when the carrier frequency interval is 6 MHz, the minimum carrier frequency is set to (6 · n + 3) MHz (n is an integer).

Further, in the analog transmission device according to the present invention, when the minimum frequency of the carrier is 55.25 MHz,
The frequency interval of the carrier is set to 6.5 MHz.

[0015]

In the present invention, as described above, the minimum frequency of carriers and the frequency interval are set to predetermined frequencies, so that the composite second-order distortion occurs at a frequency that does not hinder transmission.

Further, in the present invention, as described above, the minimum frequency of the carrier is (xn + x / 2) MHz.
Since (x is a natural number of 6 or more and n is an integer) and the frequency interval of the carrier is set to x MHz, it is necessary to generate the composite second-order distortion at a frequency that does not hinder transmission. An example of the relationship that the minimum frequency and the frequency interval should have can be actually provided.

Further, in the analog transmission device according to the present invention, when the carrier frequency interval is 6 MHz, the minimum carrier frequency is set to (6 · n + 3) MHz (n is an integer). It is possible to actually provide an example of the relationship that the minimum frequency of the carrier and the frequency interval should have in order to generate distortion at a frequency that does not hinder transmission.

Further, in the analog transmission device according to the present invention, when the minimum frequency of the carrier is 55.25 MHz,
Since the frequency interval of the carrier is set to 6.5 MHz, an example of the relationship that the minimum frequency of the carrier and the frequency interval should have in order to generate composite second-order distortion at a frequency that does not hinder transmission is actually shown. Can be provided to.

[0019]

EXAMPLES Example 1. An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 shows a state of complex second-order distortion that occurs in an analog transmission device according to an embodiment of the present invention. This FIG. 1 is a CAT as shown in FIG.
In a V system or the like, when the frequency interval of the signals of the transmission signal is 6 MHz, a composite 2 that occurs when the minimum (initial) frequency of the signals is set to (6 · n + 3) MHz (n is an integer) It shows the relationship between the secondary distortion and the signal. In the figure, 1, 2, and 3 are transmission signals output at 6 MHz intervals, and 4 is a bandwidth required to transmit a transmission signal which is a video signal, which corresponds to ± 3 MHz around the frequency of the transmission signal. It has a spread.
5 is a composite second-order distortion generated at -3 MHz of the transmission signal 2, 6
Is a complex second-order distortion generated at (frequency of the transmission signal 2 + 3) MHz.

In this embodiment, the minimum (initial) frequency of the transmission signal is (6 · n + 3) MHz, and the frequency interval is 6 MHz.
Therefore, the signal frequency is, for example, 3,
9, 15, 21, 27, 33, 39, ... MHz.

The complex second-order distortion generated at the sum or difference frequency of the signal frequencies is (6n ₁ +3) + (6n ₂ +3) = 6 (n ₁ + n ₂ ) + 6 = 6 · N ₁ or (6n ₁ + 3) − (6n ₂ +3) = 6 (n ₁ −n ₂ ) = 6 · N ₂ , which is an integer multiple of 6 in both cases 6,12,
It occurs at 18, 24, 30, 36, ... MHz.

Therefore, the complex second-order distortion with respect to the transmission signal is
It occurs at ± 3 MHz corresponding to the boundary between the bandwidths required to transmit the two transmission signals. Therefore,
As is clear from Fig. 1, the signal bandwidth is ± 3 MHz.
This means that this complex second-order distortion has no effect on.

Example 2. In the first embodiment, the minimum (initial) frequency of the transmission signal is set to (6 · n + 3) MHz, and the frequency interval is set to 6 MHz. However, the minimum frequency of the transmission signal is 55.25 MHz, The frequency interval may be 6.5 MHz and 42 channels may be transmitted.

In the case of this embodiment, the complex second-order distortion generated at the sum or difference frequency of the signal frequencies is (6.5n ₁ +3.25) + (6.5n ₂ +3.25) = 6.5. (N ₁ + n ₂ ) + 6.5 = 6.5 · N ₁ or (6.5n ₁ +3.25) − (6.5n ₂ +3.25) = 6.5 · N ₂ , and in either case 58. which is an integral multiple of 6.5.
It occurs at 5, 65, 71.5, ... MHz.

Therefore, the composite second-order distortion with respect to the transmission signal is
It occurs at (signal frequency ± 3.25) MHz. Therefore,
The complex second-order distortion occurs at a frequency outside the transmission band of ± 3 MHz and does not affect the transmission signal.

Example 3. In the second embodiment, the minimum frequency of the transmission signal is 55.25 MHz, the frequency interval is 6.5 MHz, and 42 channels are transmitted.
(Signal minimum frequency x · n + x / 2) From MHz, the frequency interval x is set to 7 and n = 7, and the minimum frequency is set to 5
Transmission may be performed at 2.5 MHz and a frequency interval of 7 MHz.

In the case of this embodiment, the complex second-order distortion generated at the sum or difference frequency of the signal frequencies is (7n ₁ +3.5) + (7n ₂ +3.5) = 7 (n ₁ + n ₂ ). + 7 = 7 · N ₁ or (7n ₁ +3.5) − (7n ₂ +3.5) = 7 · N ₂ , which is an integer multiple of 7 in either case 56,5
It occurs at 9.5, 63, ... MHz.

Therefore, the complex second-order distortion with respect to the transmission signal is
Complex second-order distortion occurs at a signal frequency of ± 3.5 MHz.
Therefore, the composite second-order distortion is generated at a frequency outside the transmission band of ± 3 MHz and does not affect the transmission signal.

In each of the above embodiments, the case of the CATV system has been described as an example, but any system can be applied as long as it transmits an analog signal at equal frequency intervals, and the same as in the above embodiments. Produce the effect of.

[0030]

As described above, according to the analog transmission device of the present invention, the initial frequency of the carrier and the frequency interval thereof are set so that the frequency of the generated complex second-order distortion can be driven out into the region that does not hinder the transmission. Since the setting is made, there is an effect that even if the complex second-order distortion occurs, it can be generated at a frequency that does not hinder the transmission.

In the analog transmission device according to the present invention, the minimum carrier frequency is (xn + x / 2) MHz.
Since (x is a natural number of 6 or more and n is an integer) and the frequency interval of the carrier is set to x MHz, it is necessary to generate the composite second-order distortion at a frequency that does not hinder transmission. There is an effect that an example of the relationship that the minimum frequency and the frequency interval should have can be actually provided.

Further, in the analog transmission device according to the present invention, when the carrier frequency interval is 6 MHz, the minimum carrier frequency is set to (6 · n + 3) MHz (n is an integer). There is an effect that it is possible to actually provide an example of the relationship that the minimum frequency of the carrier and the frequency interval must have in order to generate distortion at a frequency that does not hinder transmission.

Further, in the analog transmission device according to the present invention, when the minimum frequency of the carrier is 55.25 MHz,
Since the frequency interval of the carrier is set to 6.5 MHz, an example of the relationship that the minimum frequency of the carrier and the frequency interval should have in order to generate composite second-order distortion at a frequency that does not hinder transmission is actually shown. There is an effect that can be provided to.

[Brief description of drawings]

FIG. 1 is a diagram showing a relationship between a transmission signal and second-order composite distortion in an embodiment of the present invention.

FIG. 2 is a diagram showing a relationship between a transmission signal and a secondary composite distortion according to a conventional transmission method.

FIG. 3 is a CAT which is an example of an object to which the present invention is applied.
It is a conceptual diagram which shows a V system.

[Explanation of symbols]

 1 Transmission signal 2 Transmission signal 3 Transmission signal 4 Transmission band 5 Complex second-order distortion 6 Complex second-order distortion

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[Procedure amendment]

[Submission date] July 16, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Claim 1

[Correction method] Change

[Correction content]

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0028

[Correction method] Change

[Correction content]

[0028] Thus, the composite second-order distortion to the transmission signal,
Occur ± 3.5MHz of the signal frequency. Therefore, the composite second-order distortion is generated at a frequency outside the transmission band of ± 3 MHz and does not affect the transmission signal.

Claims (4)

[Claims] 1. In a device for transmitting a plurality of analog signals whose carrier frequencies are equidistant from each other through one transmission path, the initial frequency and frequency interval of the carrier of the analog signal do not hinder the transmission. An analog transmission device characterized by being set so that complex second-order distortion is generated in the frequency. 2. The analog transmission device according to claim 1, wherein the minimum frequency of the carrier is (x · n + x / 2) MHz.
(X is a natural number of 6 or more, n is an integer), and the frequency interval of the carrier is x MHz. 3. The analog transmission device according to claim 1, wherein when the carrier frequency interval is 6 MHz, the minimum carrier frequency is set to (6 · n + 3) MHz (n is an integer). Transmission equipment. 4. The analog transmission device according to claim 1, wherein when the minimum frequency of the carrier is 55.25 MHz,
An analog transmission device characterized in that the carrier frequency interval is set to 6.5 MHz.