JPS6318214Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a television receiver that can process video signals of PAL, SECAM, and NTSC formats. The purpose of this invention is to propose something that can substantially prevent subcarrier frequency components from being mixed into a luminance signal.

An embodiment of the present invention will be described in detail below with reference to the drawings. 1 is a composite video signal input terminal, to which composite video signals of PAL, SECAM and NTSC systems are supplied. The signal formats of the carrier color signals of these systems are as follows.

The carrier color signal of the NTSC system is a 3.58 MHz color subcarrier signal as a red difference signal RY and a blue difference signal B-.
It is quadrature two-phase modulated in Y.

The PAL carrier color signal is a red difference signal ±(R-
Y) and a blue difference signal B-Y, which are quadrature two-phase modulated.

The carrier color signal of the SECAM method is a signal obtained by FM modulating a 4.40MHz color subcarrier signal with a red difference signal R-Y, and a signal obtained by FM modulating a 4.25MHz color subcarrier signal with a blue difference signal B.
This is a line sequential signal with a signal FM modulated by -Y.

Now, the composite video signal from the input terminal 1 is supplied to a sync separation circuit 2, a band pass filter 3 for extracting the carrier color signal of PAL and NTSC systems, a chroma trap circuit 4, and a bell filter 5 for extracting the carrier color signal of the SECAM system. be done.

The synchronization signal from the synchronization separation circuit 2 is supplied to a vertical frequency discrimination circuit 6, and its discrimination output is supplied to a switching control signal generation circuit 7. Vertical frequency is 60Hz for NTSC, PAL and SECAM
In the case of the method, it is 50Hz. Then, the signal generating circuit 7 generates contradictory switching control signals depending on whether the vertical frequency is 50 Hz or 60 Hz.

The bandpass filter 3 has a switch 3a that is controlled on and off by a switching control signal from the signal generation circuit 7, so that the switch 3a is turned on and off, respectively.
The filter characteristics that can extract the carrier color signal of the NTSC system are the passband center frequency of 4.43MHz and 3.58M.
Hz and can be switched.

extracted by bandpass filter 3
PAL or NTSC carrier color signals are PAL and
The signal is supplied to the color signal processing circuit 8 for the NTSC system. The switch 8a of the color signal processing circuit 8 is controlled on and off by a switching control signal from the signal generating circuit 7, and is switched to a PAL and NTSC color signal processing circuit, respectively. In this color signal processing circuit 8, according to the PAL and NTSC systems,
Switching the oscillation frequency of its local color subcarrier oscillator,
1H (H is horizontal period of PAL system) delay line,
Whether or not to use adders and subtracters is controlled.
Note that 9 is a killer detection circuit. When monochrome and when the SECAM carrier color signal is obtained, a detection output is obtained from the killer detection circuit 9.
The killer circuit of the color signal processing circuit 8 operates. Then, the red color difference signal R obtained from the color signal processing circuit 8
-Y and blue difference signal B-Y are matrix circuit 10
is supplied to Output terminal 1 of matrix circuit 10
1R, 11G, and 11B respectively have a red signal R (or red difference signal R-Y) and a blue signal B (or blue difference signal B-
Y), a green signal G (or a green difference signal G-Y) is output.

Also, SECAM extracted by bell filter 5
The carrier color signal of the SECAM system is supplied to a color signal processing circuit 12 for the SECAM system, and the obtained red difference signal RY and blue difference signal B-Y are supplied to the matrix circuit 10. Note that 13 is a killer detection circuit. When monochrome or when a PAL or NTSC carrier color signal is obtained, the killer detection circuit 13
A detection output is obtained from the chrominance signal processing circuit 12, and the killer circuit of the color signal processing circuit 12 operates.

The luminance signal from which the color subcarrier frequency component has been removed by the chroma trap circuit 4 is supplied to a luminance signal processing circuit 14, and the signal-processed luminance signal is supplied to a matrix circuit 10. Note that 15 is an output terminal for a luminance signal that has undergone signal processing.

Next, the circuit configuration of this chroma trap circuit 4 will be explained. This chroma trap circuit 4 includes first and second trap circuits 4 connected in series.
It consists of a and 4b.

The first trap circuit 4a is PAL type 4.43MHz
The frequency characteristic substantially attenuates the color subcarrier frequency component of the color subcarrier frequency component. That is, one end of resistor R ₁ is connected to input terminal 1, both ends of resistor R ₁ are connected through a series circuit of capacitors C ₁ and C ₂ , and the midpoint of the connection of capacitors C ₁ and C ₂ is connected to coil L _1. The first trap circuit 4a is configured by being grounded through the trap circuit 4a.

A grounded emitter amplifier 4c including a transistor Q is inserted between the first and second trap circuits 4a and 4b. Note that +B is a power supply. The base of this transistor Q is connected to the other end of the resistor _R1 of the first trap circuit 4a.

Next, the second trap circuit 4b will be explained. A resistor R ₂ is connected between the collector of the transistor Q of the amplifier 4c and the input terminal of the luminance signal processing circuit 14.
is connected, and a series circuit of capacitors C ₃ and C ₄ is connected to both ends of the capacitor. A midpoint between the capacitors C ₃ and C ₄ is connected through a coil L ₂ to the collector of an npn transistor Q ₁ as a first switching element, and its emitter is grounded. The collector of the transistor Q ₁ is connected through the coil L ₃ to the collector of an npn transistor Q ₂ as a second switching element, and its emitter is grounded.

Then, the killer detection signal from the killer detection circuit 13 is supplied to the control circuit 16, and the control signal is supplied to the base of the transistor _Q1 , and the SECAM
Transistor _Q1 is made conductive only when the color signal carrying the system is available.

Further, the switching control signal from the signal generation circuit 7 is supplied to the control circuit 17, and the control signal is supplied to the base of the transistor _Q2 , and the transistor Q2 is switched on only when an NTSC carrier color signal is obtained.
Make Q ₂ conductive.

Therefore, when a PAL carrier color signal is obtained, both transistors Q ₁ and Q ₂ are turned off.

Next, the operation of this chroma trap circuit 4 will be explained. The color subcarrier frequency of the PAL system (4.43MHz) and one of the color subcarrier frequencies of the SECAM system (4.40MHz) are similar, and
The carrier color signal of the SECAM system is an FM modulated signal,
Since the energy is not concentrated in one spectrum, the trap characteristics do not need to be exact, so even when a carrier color signal of NTSC or SECAM format is obtained, the color subcarrier frequency components of PAL format are substantially attenuated. The first trap circuit 4a, which has a frequency characteristic that allows
It is not an obstacle.

In the second trap circuit 4b, when a SECAM type carrier color signal is obtained, the transistor
Only Q ₁ becomes conductive (transistor Q ₂ is non-conductive). Therefore, each element R ₂ , C ₃ ,
Due to the frequency characteristics determined by the constants of C ₄ and L ₂ ,
The 4.25 MHz color subcarrier frequency component of the SECAM system is substantially attenuated by this second trap circuit 4b. In addition, the 4.40 MHz color subcarrier frequency component of the SECAM method is transmitted to the first trap circuit 4.
It is substantially attenuated by a.

When an NTSC carrier color signal is obtained, only transistor _Q2 is conductive (transistor _Q1 is non-conductive). For this reason,
Due to the frequency characteristics determined by the constants of each element R ₂ , C ₃ , C ₄ , L ₂ , and L ₃ , the 3.58 MHz color subcarrier frequency component of the NTSC system is substantially attenuated by this second trap circuit 4b. It will be done.

Furthermore, when a PAL type carrier color signal is obtained, both transistors Q ₁ and Q ₂ are in a non-conducting state, and the second trap circuit 4b is in an inactive state. The 4.43 MHz color subcarrier frequency component of the PAL system is substantially attenuated by the first trap circuit 4a.

According to the present invention described above, PAL, SECAM and
In a television receiver capable of signal processing of any NTSC video signal, it is possible to have a simple configuration that effectively prevents the color subcarrier frequency component from being mixed into the luminance signal, regardless of the format. You can obtain something that can be prevented.

[Brief explanation of the drawing]

The figure is a block diagram showing one embodiment of the present invention. 4 is a chroma trap circuit, 4a and 4b are first and second trap circuits, and Q ₁ and Q ₂ are transistors as first and second switching elements, respectively.

Claims (1)

[Scope of utility model registration request] In a television receiver capable of processing video signals of PAL, SECAM, and NTSC formats, first and second trap circuits are connected in cascade between a composite video signal input terminal and a luminance signal processing circuit. The above first trap circuit consists of
The second trap circuit has a frequency characteristic that substantially attenuates the color subcarrier frequency component of the PAL system, and includes first and second switching elements, and when only the first switching element is in a conductive state, A frequency characteristic that substantially attenuates one color subcarrier frequency component of the SECAM method, and a frequency that substantially attenuates the color subcarrier frequency component of the NTSC method when only the second switching element is in a conductive state. What is claimed is: 1. A television receiver, characterized in that the television receiver is configured to be in a non-operating state when both the first and second switching elements are in a non-conducting state.