JPH0313183A - Muse signal receiver - Google Patents

Abstract

PURPOSE:To receive MUSE signals with different roll-off rates on a transmission line satisfactorily by providing filters with different characteristics suitable for the roll-off rates. CONSTITUTION:A low-pass filter 16 with steep characteristic of 8.1MHz serving frequency characteristic at a reception side 1/2-th power distributed so as to obtain 10% roll-off characteristic on the transmission line of the MUSE signal is provided. Also, a low-pass filter 18 with moderate characteristic of 8.1MHz serving the frequency characteristic at the reception side 1/2-th power distributed so as to obtain 30% roll-off characteristic on the transmission line of the MUSE signal, and a manual input selection switch 20 are provided. The roll-off characteristic can be realized with the low-pass filter 16 in the case of using the MUSE signal of satellite broadcast with 10% roll-off characteristic, and with the filter 18 in the case of using the MUSE signal from a VTR 12 with the 30% roll-off characteristic. Thereby, the MUSE signals with different roll-off characteristics can be received satisfactorily.

Description

DETAILED DESCRIPTION OF THE INVENTION (A) Field of Industrial Application The present invention relates to a MUSE signal receiving device that receives MUSE signals with different transmission line roll-off rates. (b) Conventional technology A multiple sub-Nyquist sampling encoding method (Mt, iSE method) was proposed by NHK as a method for band-compressing a high-quality video signal and transmitting it using a broadcasting satellite, and it has been widely used.

This method uses a single channel of satellite broadcasting (bandwidth 27M).
In order to transmit a high-quality video signal at a frequency of 8.1 MHz), this high-definition video signal is compressed by a band compression encoder to a bandwidth of 8.1 MHz.
This converts the video signal into a band-compressed video signal (MUSE signal).

The MUSE method is introduced in the following documents.

(a) NHK Technical Research, Vol. 39, No. 2, 1988, No. 172, pp. 18 (76) to 53 (111), Ninomiya,
Firebomb, Izumi, Agreement, Development of rMUSE method written by Iwadate” (b) Magazine published by Nikkei McGraw-Hill [Nikkei Electronics, November 2, 1987 issue, Nn433],
Pages 189 to 212, Ninomiya, "Transmission system for high-definition broadcasting using satellites, MUSEJ" The overall characteristics of the transmission path for this MUSE signal are set to have a point-symmetric roll-off characteristic at JIMHz, as shown in Figure 6. ing.

As is well known, the NHK standard satellite broadcast MUSE signal has a roll-off rate of [100X (fc-8,1)/8
．． 1%) is set as 10%. When the roll-off rate is small like this (i.e., when the filter characteristics are steep),
If the sample phase on the reproduction side shifts, overshoot becomes large and ringing etc. are likely to occur.

Therefore, M with high roll-off rate and resistance to ringing etc.
It is conceivable to transmit a USE signal. (c) Problems to be solved by the invention The present invention solves the problems of M with different roll-off rates.
A MUSE signal receiving device for receiving LJSE signals is provided.

(d) Means for Solving the Problems The present invention is a MUSE signal receiving device that includes filters with different characteristics that adapt to roll-off rates.

Further, the present invention adjusts the filter characteristics by adapting to the roll-off rate.
This is a MUSE signal receiving device that switches.

(E) Effect According to the present invention, the characteristics of the filter are selected according to the roll-off characteristics.

(f) Example A first embodiment of the present invention will be described with reference to FIG.

In FIG. 1, (10) is a satellite broadcast receiver (BS receiver). The roll-off rate of satellite broadcasting is <10 as mentioned above.
%. (12) is a MUSE-VTR. Ko (7
) MU S E -V T R (12) to +7) MU
The roll-off rate of the SE multiplied signal transmission path is 30%.

(14) is a MUSE decoder.

(10a) (12a) are MUSE signal output terminals, (
14a) is the MUSE signal input terminal for BSS;
b)? ! This is a MUSE signal input terminal for VTR.

In (16), the MUSE signal transmission path is 10% as before.
8. Responsible for receiving frequency characteristics distributed to the 1/2 power so as to have roll-off characteristics. This is a low-pass filter (see Fig. 2a) with steep characteristics at IMHz.

(18) has a gentle characteristic of 8.0, which has a frequency characteristic on the receiving side distributed to the 1/2 power so that the transmission path of the MUSE signal has a 30% roll-off characteristic. This is an IMHz low-pass filter (see Figure 2).

(20) is a manual input selection switch. (22) is M
This is a USE signal processing circuit.

In the above circuit, in the case of a satellite broadcast MUSE signal with a 10% roll-off characteristic, a steep low-pass filter (1
6) realizes the roll-off characteristic. And VTR (12) which is a roll-off characteristic of 30%
In the case of transmitting the MUSE signal from the MUSE signal, a smooth low-pass filter (18) is used to realize the roll-off characteristic.

A second embodiment of the present invention will be described with reference to FIGS. 3 to 5.

In Fig. 3, (14c) is the MUSE signal input terminal;
(24) is an A/D converter, and (26) is a control signal detection circuit. (28) is a filter circuit.

First, MtJSE-VTR (12) or BS receiver (1o
) will be explained regarding the MUSE signal output from the MUSE signal.

The format of the well-known MUSE signal is shown in FIG. The control signals in FIG. 4 consist of various signals for decoding the MUSE signal. This control signal usually consists of 32 bits. This control signal (32
Figure 5 shows the contents of the bits. In the present invention, a broadcast/non-broadcast discrimination code signal is set in this control signal, and this discrimination code signal is used to control the switch (2').
).

In this embodiment, as shown in FIG. 5, a broadcast/non-broadcast discrimination code signal is written in the 19th bit of the control signal, which was previously an empty pit.

For example, a broadcast station broadcasts a MUSE signal with this broadcast/non-broadcast discrimination code signal "l" at the time of broadcast. Also, video software companies use this broadcast/non-broadcast discrimination code signal as "0" when producing video disc software or video tape software.
” Recording is performed using the MUSE signal. Furthermore, home video tape recorders (VTRs) and recordable home video disc players replace the 19th bit of this control signal with "0" when recording.

For safety reasons, even if you play software that has not been replaced in this way, you will need to make sure that it works properly.
Processing may also be performed to replace the 19th bit of this control signal with "0".

In the present invention, among the control signals shown in FIG. 5 detected by the control signal detection circuit (26), the aforementioned broadcast/non-broadcast identification code signal is output to the changeover switch (20°). The changeover switch (20') uses this code signal to select the filter (16) when receiving a broadcast signal, and selects the filter (18) when receiving a non-broadcast signal.

In the above embodiment, two MUSE signals with roll-off rates of 10% and 30% were used as an example, but the present application is not limited thereto.

Further, although the roll-off rate was determined using the broadcast/non-broadcast identification code signal, a signal directly indicating the roll-off rate may be inserted into the control signal.

(G) - Effects of the Invention As described above, according to the present invention, MUSE signals with different roll-off characteristics can be received satisfactorily.

[Brief explanation of drawings]

FIG. 1 is a diagram showing a first embodiment of the present invention. FIG. 2 is a diagram showing the filter characteristics. FIG. 3 is a diagram showing a second embodiment of the present invention. FIG. 4 is a diagram showing the MUSE signal. FIG. 5 is a diagram showing control signals. FIG. 6 is a diagram for explaining roll-off characteristics. (16)...Low pass filter (II close filter), (18)...Low pass filter (120-pass filter), (14a) (14b)...Input terminal (selection means), (
20)...Switch (selection means), (28)...Filter circuit, (26)...Control signal detection circuit, (20')
...Switch (switching circuit). Figure 1 1/. Figure 2

Claims (2)

[Claims] (1) The first low-pass filter (1
6), and a second low-pass filter (18
), and selection means (14a) (14b) (2) for selectively passing the MUSE signal to the first or second low-pass filter.
0); A MUSE signal receiving device comprising: (2) Filter circuit (28
), a control signal detection circuit (26) that demodulates the control signal of the MUSE signal and outputs a broadcast/non-broadcast discrimination code signal; A MUSE signal receiving device comprising: a switching circuit (20') that steepens the passage characteristic of the filter circuit (28) when a signal indicates that a broadcast signal is being input.