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United States Patent |
5,198,891
|
Gai
|
March 30, 1993
|
Brightness signal/color signal separation filter including an image
correction judging circuit
Abstract
A filter for separating brightness signal and color signal from a composite
color signal of NTSC type or PAL type, includes a horizontal color signal
extracting filter, a vertical color signal extracting filter, a
horizontal/vertical color signal extracting filter, a switching circuit,
and an image correlation judging circuit. The image correlation judging
circuit makes the switching circuit select: the color signal extracted by
the horizontal color signal extracting filter when the horizontal
correlation is judged to be stronger than the sampling value at the target
sampling point; the color signal extracted by the vertical color signal
extracting filter when the vertical correlation is judged to be stronger
than the same; and the color signal extracted by the horizontal/vertical
color signal extracting filter when neither of them is judged to be
stronger than the same. The result is that mutual leakage of the
brightness signal and the color signal at the area of intensive change
into the another's channel can be reduced, thereby avoiding dot jamming
and deterioration of image quality. The image correlation judging circuit
judges the strength of correlation based on the non-correlative energy.
Inventors:
|
Gai; Toshihiro (Nagaokakyo, JP)
|
Assignee:
|
Mitsubishi Denki Kabushiki Kaisha (Tokyo, JP)
|
Appl. No.:
|
825786 |
Filed:
|
January 21, 1992 |
Foreign Application Priority Data
| Dec 08, 1989[JP] | 1-319550 |
| Mar 14, 1990[JP] | 2-63131 |
| Jul 11, 1990[JP] | 2-184640 |
Intern'l Class: |
H04N 009/78 |
Field of Search: |
358/31,37,39,40
|
References Cited
U.S. Patent Documents
4707132 | Nov., 1987 | Matono et al.
| |
4754322 | Jun., 1988 | Okuda et al. | 358/31.
|
4789890 | Dec., 1988 | Ito et al. | 358/31.
|
4954885 | Sep., 1990 | Ito et al. | 358/31.
|
4994906 | Feb., 1991 | Moriwake | 358/31.
|
Foreign Patent Documents |
26677A1 | Feb., 1986 | DE.
| |
28699A1 | Feb., 1986 | DE.
| |
61-18285 | Jan., 1986 | JP.
| |
63-232594 | Sep., 1988 | JP.
| |
2226207A | Jun., 1990 | GB.
| |
Other References
NTSC Y/C Separation and Enhancement Technique with Two Dimensional Adaptive
Features to M. Itoga et al, IEEE Transactions on Consumer Electronics,
vol. 34, No. 1, Feb. 1988.
John P. Rossi, "Digital TV Comb Filter With Adaptive Features", IERE Conf.
Proc. pp. 267-282 (1976).
John P. Rossi, "Digital Television Image Enhancement" J. Smpte, vol. 84,
Jul. (1985).
|
Primary Examiner: Coles, Sr.; Edward L.
Assistant Examiner: Vu; Kim Yen
Parent Case Text
This application is a continuation of application Ser. No. 07/623,088 filed
on Dec. 6, 1990, now abandoned.
Claims
What is claimed is:
1. A brightness signal/color signal separating filter for separating a
brightness signal and a color signal from an input composite color
television signal, comprising:
a first delay circuit for outputting a first delay composite television
signal generated by delaying the input composite color signal by a
predetermined number of lines;
a second delay circuit for outputting a second delay composite color
television signal generated by further delaying the input composite color
signal delayed by said first delay circuit by an equal number of lines as
delayed in said first delay circuit;
a vertical color signal extracting filter for extracting vertical color
signal from the input composite color television signal, first delay
composite color television signal, and second delay composite color
television signal;
a horizontal color signal extracting filter for extracting horizontal color
signal from the first delay composite color television signal;
a horizontal/vertical color signal extracting filter for extracting
horizontal and vertical color signals from said input, first delay and
second delay composite color television signals;
a switching circuit for selectively outputting any one of outputs from said
vertical color signal extracting filter, horizontal color signal
extracting filter, and horizontal/vertical color signal extracting filter;
and
an image correlation judging circuit for comparatively judging correlation
of an image by said input, first delay and second delay composite color
television signals in the vertical and horizontal directions, and for
outputting horizontal color signal when horizontal correlation in strong,
for outputting vertical color signal when vertical correlation is strong
and the horizontal correlation is weak, and for outputting both horizontal
and vertical color signals when both the horizontal and vertical
correlations are weak, respectively, from said switching circuit;
said image correlation judging circuit including,
(a) non-correlative energy extracting means for extracting horizontal color
signal non-correlative energy representative of correlative strength of
the horizontal color signal, horizontal brightness signal non-correlative
energy representative of correlative strength of the horizontal brightness
signal, vertical color signal non-correlative energy representative of
correlative strength of the vertical color signal, and vertical brightness
signal non-correlative energy representative of correlative strength of
the vertical brightness signal;
(b) comparative signal generating means for generating four comparative
signals representative of vertical and horizontal correlative strengths of
the composite color television signal, one based on horizontal color
signal non-correlative energy, horizontal brightness signal
non-correlative energy, vertical color signal non-correlative energy, and
vertical brightness signal non-correlative energy, respectively,
(c) comparative judging means for comparatively judging the horizontal and
vertical correlative strengths of the composite color television signal,
and for controlling said switching circuit to output horizontal color
signal extracted by the horizontal color signal extracting circuit when
the horizontal correlation is strong, vertical color signal extracted by
the vertical color signal extracting filter when vertical correlation is
stronger than horizontal correlation, and horizontal/vertical color
signals extracted by the horizontal/vertical color signal extracting
filter when both the horizontal and vertical correlations are weak.
2. A brightness signal/color signal separating filter according to claim 1,
wherein said input composite color television signal is an NTSC (National
Television System Committee) signal.
3. A brightness signal/color signal separating filter according to claim 2,
wherein said non-correlative energy extracting means comprises:
(a) a horizontal color signal non-correlative energy extracting circuit for
extracting horizontal color signal non-correlative energy from the first
delayed composite color television signal;
(b) a horizontal brightness signal non-correlative energy extracting
circuit for extracting horizontal brightness signal non-correlative energy
from the input composite color television signal, the first delayed
composite color television signal and the second delayed composite color
television signal;
(c) a vertical color signal non-correlative energy extracting circuit for
extracting vertical color signal non-correlative energy from the input
composite color television signal, and the second delayed composite color
television signal; and
(d) a vertical brightness signal non-correlative energy extracting circuit
for extracting vertical brightness signal non-correlative energy from the
input composite color television signal, the first delayed composite color
television signal, and the second delayed composite color television
signal.
4. A brightness signal/color signal separating filter according to claim 3,
wherein each of said horizontal color signal non-correlative energy
extracting circuit, said horizontal brightness signal non-correlative
energy extracting circuit, said vertical color signal non-correlative
energy extracting circuit and said vertical brightness signal
non-correlative energy extracting circuit is a finite impulse response
filter.
5. A brightness signal/color signal separating filter according to claim 4,
wherein said horizontal color signal non-correlative energy extracting
circuit further comprises:
delay means for delaying the first delayed composite color television
signal by one cycle of a color subcarrier;
subtracting means for subtracting an output of said delay means from input
to said delay means;
absolute value calculating means for calculating an absolute value of an
output of said subtracting means and for outputting the absolute value as
horizontal color signal non-correlative energy.
6. A brightness signal/color signal separating filter according to claim 4,
wherein said horizontal brightness signal non-correlative energy
extracting circuit further comprises:
a vertical low pass filter for low pass-filtering the inputted composite
color television signal, the first delayed composite color television
signal and the second delayed composite color television signal;
first delay means for delaying and subsequently outputting an output of
said vertical low pass filter by a half of a cycle of the color
subcarrier;
second delay means for delaying the output of said first delay means by a
half of the cycle of the color subcarrier;
first subtracting means for subtracting the output of said first delay
means from an output of said vertical low pass filter;
second subtracting means for subtracting and subsequently outputting an
output of said second delay means from the output of said first delay
means;
first absolute value calculating means for calculating and subsequently
outputting an absolute value of an output of said first subtracting means;
second absolute value calculating means for calculating and subsequently
outputting an absolute value of the output of said second subtracting
means; and
maximum value calculating means for selecting a larger of the outputs of
said first absolute value calculating means and said second absolute value
calculating means and for outputting the larger as horizontal brightness
signal non-correlative energy.
7. A brightness signal/color signal separating filter according to claim 4,
wherein said vertical color signal non-correlative energy extracting
circuit further comprises:
a first horizontal band pass filter for band pass-filtering and
subsequently outputting the input composite color television signal;
a second horizontal band pass filter for band filtering and subsequently
outputting the second delayed composite color television signal;
subtracting means for subtracting an output of said second vertical band
pass filter from an output of said first vertical band pass filter; and
absolute value calculating means for calculating and subsequently
outputting an absolute value of the output of said subtracting means as
vertical color signal non-correlative energy.
8. A brightness signal/color signal separating filter according to claim 4,
wherein said vertical brightness signal non-correlative energy extracting
circuit further comprises:
a first horizontal low pass filter for low pass-filtering and subsequently
outputting the input composite color television signal;
a second horizontal low pass filter for low pass-filtering and subsequently
outputting the first delayed composite color television signal;
a third horizontal low pass filter for low pass-filtering and subsequently
outputting the second delayed composite color television signal;
first subtracting means for subtracting and subsequently outputting the
output of said second horizontal low pass filter from the output of said
first horizontal low pass filter;
second subtracting means for subtracting and subsequently outputting the
output of said third horizontal low pass filter from the output of said
second horizontal low pass filter;
first absolute value calculating means for calculating and subsequently
outputting an absolute value of the output of said first subtracting
means;
second absolute value calculating means for calculating and subsequently
outputting an absolute value of the output of said second subtracting
means; and
maximum value calculating means for selecting a larger of the outputs of
said first absolute value calculating means and said second absolute value
calculating means and outputting the larger as vertical brightness signal
non-correlative energy.
9. A brightness signal/color signal separating filter according to claim 2,
wherein said comparative judging means further comprises:
a first comparing circuit for comparing the first comparative signal with
the third comparative signal, and for judging the vertical correlation as
strong and the horizontal correlation as weak when the first comparative
signal is larger than the third comparative signal, and for judging the
vertical correlation as weak when the third comparative signal is larger
than the first comparative signal;
a second comparing circuit for comparing the second comparative signal with
the fourth comparative signal, and for judging the horizontal correlation
as weak when the second comparative signal is larger than the fourth
comparative signal, and for judging the horizontal correlation as strong
and the vertical correlation as weak when the fourth comparative signal is
larger than the second comparative signal; and
a judging circuit for controlling said switching circuit based on the
compared results by said first comparing circuit and said second comparing
circuit.
10. A brightness signal/color signal separating filter according to claim
9, wherein:
said first comparing circuit comprises a means for outputting the value "1"
when judging the vertical correlation as strong and the horizontal
correlation as weak, and for outputting the value "0" when judging the
vertical correlation as weak;
said second comparing means comprises a means for outputting the value "1"
when judging the horizontal correlation as strong and the vertical
correlation as weak, and for outputting the value "0" when judging the
horizontal correlation as weak; and
said judging means further including a first NOT circuit for rendering a
logical negation of an output of said first comparing circuit, a second
NOT circuit for rendering a logical negation of an output of said second
comparing circuit, a first AND circuit for rendering a logical product of
an output of said first comparing circuit and an output of said second NOT
circuit, and a second AND circuit for rendering a logical product of an
output of said second comparing circuit and an output of said first NOT
circuit.
11. A brightness signal/color signal separating filter according to claim
2, wherein said comparative signal generating means comprises:
a first multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined first constant and outputting
the multiplied result;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined second constant and outputting
the multiplied result;
a third multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined third constant, different from
the first constant, and outputting the multiplied result;
a fourth multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined fourth constant, different from
the second constant, and outputting the multiplied result;
a fifth multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined fifth constant and outputting
the multiplied result;
a sixth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined sixth constant and outputting
the multiplied result;
a seventh multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined seventh constant, different from
the fifth constant, and outputting the multiplied result;
an eight multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined eighth constant, different from
the sixth constant, and outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier with the output of the second multiplier, and for selecting and
outputting the larger as the first comparative signal;
a second maximum value circuit for comparing the output of the third
multiplier with the output of the fourth multiplier, and for selecting and
outputting the larger;
a third maximum circuit for comparing the output of said fifth multiplier
with the output of the sixth multiplier, and for selecting and outputting
the larger;
a fourth maximum circuit for comparing the output of said seventh
multiplier with the output of said eighth multiplier, and for selecting
and outputting the larger as the fourth comparative signal;
a ninth multiplier for multiplying the output of said second maximum value
circuit by a predetermined ninth constant and for outputting the
multiplied result as the second comparative signal; and
a tenth multiplier for multiplying the output of said third maximum value
circuit by a predetermined tenth constant and for outputting the
multiplied result as the third comparative signal.
12. A brightness signal/color signal separating filter according to claim
2, wherein said comparative signal generating means comprises:
a first adder for adding the horizontal color signal non-correlative energy
to the horizontal brightness signal non-correlative energy and for
outputting the added result as the second comparative signal;
a second adder for adding the vertical color signal non-correlative energy
to the vertical brightness signal non-correlative energy and for
outputting the added result as the third comparative signal;
a first multiplier for multiplying the second comparative signal by a
predetermined constant and for outputting the multiplied result as the
first comparative signal; and
a second multiplier for outputting the third comparative signal by a
predetermined constant and for outputting the multiplied result as the
fourth comparative signal.
13. A brightness signal/color signal separating filter according to claim
2, wherein said comparative signal generating means further comprises:
a first multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined constant and for outputting the
multiplied value;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined value and for outputting the
multiplied value;
a third multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined constant and for outputting the
multiplied value;
a fourth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined constant and for outputting the
multiplied value;
a first maximum value circuit for comparing the output of said first
multiplier with the output of said second multiplier, and for selecting
and outputting the larger;
a first adder for adding the horizontal color signal non-correlative energy
with the horizontal brightness signal non-correlative energy, and for
outputting the added result as the second comparative signal;
a second adder for adding the vertical color signal non-correlative energy
and the vertical brightness signal non-correlative energy, and for
outputting the added result as the third comparative signal;
a second maximum value circuit for comparing the output of said third
multiplier with the output of said fourth multiplier, and for selecting
and outputting the larger;
a fifth multiplier for multiplying the output of said first maximum value
circuit by a predetermined constant and for outputting the multiplied
result as the first comparative signal;
a sixth multiplier for multiplying the output of said second maximum value
circuit by a predetermined constant and for outputting the multiplied
result as the fourth comparative signal.
14. A brightness signal/color signal separating filter according to claim
2, wherein said comparative signal generating means comprises:
a first multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined first constant and for
outputting the multiplied result;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined second constant and for
outputting the multiplied result;
a third multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined third constant, different from
the first constant, and for outputting the multiplied result;
a fourth multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined fourth constant, different from
the second constant, and for outputting the multiplied result;
a fifth multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined fifth constant and for
outputting the multiplied result;
a sixth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined sixth constant and for
outputting the multiplied result;
a seventh multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined seventh constant, different from
the fifth constant, and for outputting the multiplied result;
an eighth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined eighth constant, different from
the sixth constant, and for outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier with the output of said second multiplier, and for selecting
and outputting the larger as the first comparative signal;
a second maximum value circuit for comparing the output of said third
multiplier with the output of said fourth multiplier, and for selecting
and outputting the larger;
an adder for adding the output of said fifth multiplier to the output of
said sixth multiplier and for outputting the added result;
a third multiplier for comparing the output of said seventh multiplier and
the output of said eighth multiplier, and for selecting and outputting the
larger as the fourth comparative signal;
a ninth multiplier for multiplying the output of said second maximum value
circuit by a predetermined ninth constant and for outputting the
multiplied result as the second comparative signal;
a tenth multiplier for multiplying the output of said adder by a
predetermined tenth constant and for outputting the multiplied result as
the third comparative signal.
15. A brightness signal/color signal separating filter according to claim
2, wherein said comparative signal generating means comprises:
a first multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined first constant and for
outputting the multiplied result;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined second constant and for
outputting the multiplied result;
a third multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined third constant, different from
the first constant, and for outputting the multiplied result;
a fourth multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined fourth constant, different from
the second constant, and for outputting the multiplied result;
a fifth multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined fifth constant and for
outputting the multiplied result;
a sixth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined sixth constant and for
outputting the multiplied result;
a seventh multiplier for multiplying the vertical color signal
non-correlative energy by a predetermined seventh constant, different from
the fifth constant, and for outputting the multiplied result;
an eighth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined eighth constant, different from
the sixth constant, and for outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier with the output of said second multiplier, and for selecting
and outputting the multiplied result as the first comparative signal;
an adder for adding the output of said third multiplier to the output of
said fourth multiplier;
a second maximum value circuit for comparing the output of said fifth
multiplier with the output of said sixth multiplier, and for selecting and
outputting the larger;
a third maximum value circuit for comparing the output of said seventh
multiplier with the output of said eighth multiplier, and for selecting
and outputting the larger as the fourth comparative signal;
a ninth multiplier for multiplying the output of said adder by a
predetermined ninth constant and for outputting the multiplied result as a
second comparative signal;
a tenth multiplier for multiplying the output of said second maximum value
circuit by a predetermined tenth constant and for outputting the
multiplied result as a third comparative signal.
16. A brightness signal/color signal separating filter according to claim
1, wherein said input composite color television signal is a PAL signal.
17. A brightness signal/color signal separating filter according to claim
2, wherein said non-correlative energy extracting means comprises:
(a) a first horizontal color signal non-correlative energy extracting
circuit for extracting first horizontal color signal non-correlative
energy from the input composite color television signal, the first delayed
composite color television signal, and the second delayed composite color
television signal;
(b) a second horizontal color signal non-correlative energy extracting
circuit for extracting second horizontal color signal non-correlative
energy from the first delayed composite color television signal;
(c) a horizontal brightness signal non-correlative energy extracting
circuit for extracting horizontal brightness signal non-correlative energy
from the input composite color television signal, the first delayed
composite color television signal and the second delayed composite color
television signal;
(d) a first vertical color signal non-correlative energy extracting circuit
for extracting first vertical color signal non-correlative energy from the
input composite color television signal, the first delayed composite color
television signal, and the second delayed composite color television
signal;
(e) a second vertical color signal non-correlative energy extracting
circuit for extracting second vertical color signal non-correlative energy
from the input composite color television signal and the second delayed
composite color television signal;
(f) a vertical brightness signal non-correlative energy extracting circuit
for extracting vertical brightness signal non-correlative energy from the
input composite color television signal and the second delayed composite
color television signal.
18. A brightness signal/color signal separating filter according to claim
17, wherein said comparative signal generating means comprises:
a first multiplier for multiplying the first horizontal color signal
non-correlative energy by a predetermined first constant and for
outputting the multiplied result;
a second multiplier for multiplying the horizontal brightness signal by a
predetermined second constant and for outputting the multiplied result;
a third multiplier for multiplying the second horizontal color signal
non-correlative energy by a predetermined third constant and for
outputting the multiplied result;
a fourth multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined fourth constant, different from
the second constant, and for outputting the multiplied result;
a fifth multiplier for multiplying the first vertical color signal
non-correlative energy by a predetermined fifth constant and for
outputting the multiplied result;
a sixth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined sixth constant and for
outputting the multiplied result;
a seventh multiplier for multiplying the second vertical color signal
non-correlative energy by a predetermined seventh constant and for
outputting the multiplied result;
an eighth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined eighth constant, different from
the sixth constant, and for outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier with the output of said second multiplier, and for selecting
and outputting the larger as the first comparative signal;
a second maximum value circuit for comparing the output of said third
multiplier with the output of said fourth multiplier, and for selecting
and outputting the larger;
a third maximum value circuit for comparing the output of said fifth
multiplier with the output of said sixth multiplier, and for selecting and
outputting the larger as the third comparative signal;
a fourth maximum value circuit for comparing the output of said seventh
multiplier with the output of said eighth multiplier, and for selecting
and outputting the larger;
a ninth multiplier for multiplying the output of said second maximum value
circuit by a predetermined constant and for outputting the multiplied
result as a second comparative signal;
a tenth multiplier for multiplying the output of said fourth maximum value
circuit by a predetermined constant and for outputting the multiplied
result as the fourth comparative signal.
19. A brightness signal/color signal separating filter according to claim
17, wherein said comparative signal generating means comprises:
a first multiplier for multiplying the first horizontal color signal
non-correlative energy by a predetermined first constant and for
outputting the multiplied result;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined second constant and for
outputting the multiplied result;
a third multiplier for multiplying the second horizontal color signal
non-correlative energy by a predetermined third constant and for
outputting the multiplied result;
a fourth multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined fourth constant, different from
the second constant, and for outputting the multiplied result;
a fifth multiplier for multiplying the first vertical color signal
non-correlative energy by a predetermined fifth constant and for
outputting the multiplied result;
a sixth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined sixth constant and for
outputting the multiplied result;
a seventh multiplier for multiplying the second vertical color signal
non-correlative energy by a predetermined seventh constant and for
outputting the multiplied result;
an eighth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined eighth constant, different from
the sixth constant, and for outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier with the output of said second multiplier and for selecting and
outputting the larger as the first comparative signal;
a second maximum value circuit for comparing the output of said third
multiplier with output of said fourth multiplier, and for selecting and
outputting the larger;
a third maximum value circuit for comparing the output of said fifth
multiplier with the output of said sixth multiplier, and for selecting and
outputting the larger as the third comparative signal;
an adder for adding the output of said seventh multiplier to the output of
said eighth multiplier and for outputting the added result;
a ninth multiplier for multiplying the output of said second maximum value
circuit by a predetermined ninth constant and for outputting the
multiplied result as the second comparative signal;
a tenth multiplier for multiplying the output of said adder by a
predetermined tenth constant and for outputting the multiplied result as
the fourth comparative signal.
20. A brightness signal/color signal separating filter according to claim
17, wherein said comparative signal generating means comprises:
a first multiplier for multiplying the horizontal color signal
non-correlative energy by a predetermined first constant and for
outputting the multiplied result;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined second constant and for
outputting the multiplied result;
a third multiplier for multiplying the second horizontal color signal
non-correlative energy by a predetermined third constant and for
outputting the multiplying result;
a fourth multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined fourth constant, different from
the second constant, and for outputting the multiplied result;
a fifth multiplier for multiplying the first vertical color signal
non-correlative energy by a predetermined fifth constant and for
outputting the multiplied result;
a sixth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined sixth constant and for
outputting the multiplied result;
a seventh multiplier for multiplying the second vertical color signal
non-correlative energy by a predetermined seventh constant and for
outputting the multiplied result;
an eighth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined eight constant, different from
the sixth constant, and for outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier to the output of said second multiplier, and for selecting and
outputting the larger as the first comparative signal;
an adder for adding the output of said third multiplier to the output of
said fourth multiplier;
a second maximum value circuit for comparing the output of said fifth
multiplier with the output of said sixth multiplier, and for selecting and
outputting the larger as the third comparative signal;
a third maximum value circuit for comparing the output of said seventh
multiplier with the output of said eighth multiplier, and for selecting
and outputting the larger;
a ninth multiplier for multiplying the output of said adder by a
predetermined ninth constant and for outputting the multiplied result as
the second comparative signal;
a tenth multiplier for multiplying the output of said third maximum value
circuit by a predetermined tenth constant and for outputting the
multiplied result as the fourth comparative signal.
21. A brightness signal/color signal separating filter according to claim
17, wherein said comparative signal generating means comprises:
a first adder for adding the first horizontal color signal non-correlative
energy with the horizontal brightness signal non-correlative energy and
for outputting the added result as the first comparative signal;
a second adder for adding the second horizontal color signal
non-correlative energy with the horizontal brightness signal
non-correlative energy and for outputting the added result;
a third adder for adding the first vertical color signal non-correlative
energy with the vertical color brightness signal non-correlative energy
and for outputting the added result as the third comparative signal;
a fourth adder for adding the second vertical color signal non-correlative
energy with the vertical brightness signal non-correlative energy and for
outputting the added result;
a first multiplier for multiplying the output of said second adder by a
predetermined first coefficient and for outputting the multiplied result
as the second comparative signal;
a second multiplier for multiplying the output of said fourth adder by a
predetermined second coefficient and for outputting the multiplied result
as the fourth comparative signal.
22. A brightness signal/color signal separating filter according to claim
17, wherein said comparative signal generating means comprises:
a first adder for adding the first horizontal color signal non-correlative
energy with the horizontal brightness signal non-correlative energy and
for outputting the added result as the first comparative signal;
a first multiplier for multiplying the second horizontal color signal
non-correlative enerby by a predetermined first coefficient and for
outputting the multiplied result;
a second multiplier for multiplying the horizontal brightness signal
non-correlative energy by a predetermined second coefficient and for
outputting the multiplied result;
a first maximum value circuit for comparing the output of said first
multiplier with the output of said second multiplier, and for selecting
and outputting the larger;
a second adder for adding the first vertical color signal non-correlative
energy with the vertical brightness signal non-correlative energy and for
outputting the added result as the third comparative signal;
a third multiplier for multiplying the second vertical color signal
non-correlative energy by a predetermined third coefficient and for
outputting the multiplied result;
a fourth multiplier for multiplying the vertical brightness signal
non-correlative energy by a predetermined fourth coefficient and for
outputting the multiplied result;
a second maximum value circuit for comparing the output of said third
multiplier with the output of said fourth multiplier, and for selecting
and outputting the larger;
a fifth multiplier for multiplying the output of said first maximum value
circuit by a predetermined fifth coefficient and for outputting the
multiplied result as the second comparative signal;
a sixth multiplier for multiplying the output of said second maximum value
circuit by a predetermined sixth coefficient and for outputting the
multiplied result as the fourth comparative signal.
23. A brightness signal/color signal separating filter for separating a
brightness signal and a color signal from an input composite color
television signals, comprising:
means for extracting a sampled value at both a target sampling point and a
plurality of reference sampling points proximate to the target sampling
point from predetermined lines of the input composite color television
signal, synchronously, with a horizontal scanning frequency;
a horizontal color signal extracting filter for producing a first color
signal by extracting a component having a color sub-carrier frequency in a
horizontal direction relative to sampled values of predetermined sampling
points;
a vertical color signal extracting filter for producing a second color
signal by extracting a component having a color sub-carrier frequency in a
vertical direction relative to sampled values of predetermined sampling
points;
a horizontal/vertical color signal extracting filter for producing a third
color signal by extracting a component having a color sub-carrier
frequency in both vertical and horizontal directions relative to sampled
values of each of predetermined sampling points;
a switching circuit for producing an output as a separated color signal by
selecting one of the first, the second and the third color signal;
an image correlation judging circuit for outputting a selection signal by
detecting image correlations along the vertical and the horizontal
directions, respectively, from the sampled values of predetermined
sampling points;
a subtracter for outputting a brightness signal by effecting a subtraction
of the separated color signal from the composite color television signal;
said image correlation judging circuit further including,
non-correlative energy extracting means for extracting horizontal color
signal non-correlative energy representative of correlative strength of
the color signal in horizontal direction, horizontal brightness signal
non-correlative energy representative of correlative strength of the
brightness signal in horizontal direction, vertical color signal
non-correlative energy representative of correlative strength of the color
signal in vertical direction, and vertical brightness signal
non-correlative energy representative of correlative strength of the
brightness signal in vertical direction;
comparative signal generating means for generating comparative signals by
detecting a degree of image correlations in the vertical direction and in
the horizontal direction, respectively, based upon horizontal color signal
non-correlative energy, horizontal brightness signal non-correlative
energy, vertical color signal non-correlative energy, and vertical
brightness signal non-correlative energy; and
comparative judging means for controlling the switching circuit by judging
image correlation from the generated comparative signals in such a manner
that the first color signal is selected in a case of the weak correlation
in the vertical direction, the second color signal is selected in a case
of the weak correlation in the horizontal direction, and the third color
signal is selected upon neither of the first and second cases being
satisfied.
24. A brightness signal/color signal separating filter comprising:
means for delaying a composite video signal which is sampled at a frequency
synchronous with a horizontal scanning frequency by one or two lines and
simultaneously extracting the sampled values at the object sampling point
and a plurality of reference sampling points in the vicinity thereof;
a horizontal color signal extracting filter for extracting the frequency
component which corresponds to a color subcarrier frequency component in
the horizontal scanning direction on the basis of the sampled values at
the respective sampling points and outputting the extracted component as a
first color signal;
a vertical color signal extracting filter for extracting the frequency
component which corresponds to a color subcarrier frequency component in
the vertical scanning direction on the basis of the sampled values at the
respective sampling points and outputting the extracted component as a
second color signal;
a horizontal/vertical color signal extracting filter for extracting the
frequency component which corresponds to a color subcarrier frequency
component in the horizontal scanning direction and the vertical scanning
direction on the basis of the sampled values at the respective sampling
points and outputting the extracted component as a third color signal;
a switching circuit for selecting one from said first color signal, said
second color signal and said third color signal and outputting the
selected signal as a separated color signal;
image correlation judging means for outputting a color signal selection
signal by detecting the image correlations in the vertical and horizontal
scanning directions, respectively, from the sampled values of the
respective sampling points; and
a subtractor for subtracting the separated color signal from the sampled
values at the respective sampling points and outputting the signal
obtained as a separated brightness signal;
said image correlation judging means including;
horizontal brightness signal non-correlative energy detecting means for
detecting the correlation strength of the brightness signal in the
horizontal scanning direction from the sampled values at the respective
sampling points;
horizontal color signal non-correlative energy detecting means for
detecting the correlation strength of the color signal in the horizontal
scanning direction;
vertical brightness signal non-correlative energy detecting means for
detecting the correlation strength of the brightness signal in the
vertical scanning direction;
vertical color signal non-correlative energy detecting means for detecting
the correlation strength of the color signal in the vertical scanning
direction;
a comparative signal generating means for comparing the vertical
non-correlation with the horizontal non-correlation on the basis of the
horizontal brightness signal non-correlative energy, horizontal color
signal non-correlative energy, vertical brightness signal non-correlative
energy and vertical color signal non-correlative energy and supplying a
first comparative signal to said switching circuit when the vertical
non-correlation is judged to be a predetermined amount greater than the
horizontal non-correlation, a second comparative signal when the
horizontal non-correlation is judged to be a predetermined amount greater
than the vertical non-correlation, and a third comparative signal when
neither of the above two conditions exist; and
color signal extracting means for controlling said switching circuit so as
to select said first color signal, said second color signal and said third
color signal when the comparative signals received from said comparative
signal generating means are said first comparative signal, said second
comparative signal and said third comparative signal, respectively.
25. The brightness signal/color signal separating filter of claim 24
wherein said means for delaying includes,
a first delay circuit for outputting a first delay composite television
signal generated by delaying the input composite color signal by a
predetermined number of lines;
a second delay circuit for outputting a second delay composite color
television signal generated by further delaying the input composite color
signal delayed by said first delay circuit by an equal number of lines as
delayed in said first delay circuit.
26. A brightness signal/color signal separating filter according to claim
24, wherein said composite video signal is an NTSC (National Television
System Committee) signal.
27. The brightness signal/color signal separating filter of claim 24
further comprising compensating delay means disposed between said
switching circuit and said horizontal, vertical and horizontal/vertical
color signal extracting filters.
28. A brightness signal/color signal separating filter comprising:
means for delaying a composite video signal which is sampled at a frequency
synchronous with a horizontal scanning frequency by one or two lines and
simultaneously extracting the sampled values at the object sampling point
and a plurality of reference sampling points in the vicinity thereof;
a horizontal color signal extracting filter for extracting the frequency
component which corresponds to a color subcarrier frequency component in
the horizontal scanning direction on the basis of the sampled values at
the respective sampling points and outputting the extracted component as a
first color signal;
a vertical color signal extracting filter for extracting the frequency
component which corresponds to a color subcarrier frequency component in
the vertical scanning direction on the basis of the sampled values at the
respective sampling points and outputting the extracted component as a
second color signal;
a horizontal/vertical color signal extracting filter for extracting the
frequency component which corresponds to a color subcarrier frequency
component in the horizontal scanning direction and the vertical scanning
direction on the basis of the sampled values at the respective sampling
points and outputting the extracted component as a third color signal;
a switching circuit for selecting one from said first color signal, said
second color signal and said third color signal and outputting the
selected signal as a separated color signal;
image correlation judging means for outputting a color signal selection
signal by detecting the image correlations in the vertical and horizontal
scanning directions, respectively, from the sampled values of the
respective sampling points; and
a subtracter for subtracting the separated color signal from the sampled
values at the respective sampling points and outputting the signal
obtained as a separated brightness signal;
said image correlation judging means including;
horizontal brightness signal non-correlative energy detecting means for
detecting the correlation strength of the brightness signal in the
horizontal scanning direction from the sampled values at the respective
sampling points;
horizontal color signal non-correlative energy detecting means for
detecting the correlation strength of the color signal in the horizontal
scanning direction;
vertical brightness signal non-correlative energy detecting means for
detecting the correlation strength of the brightness signal in the
vertical scanning direction;
vertical color signal non-correlative energy detecting means for detecting
the correlation strength of the color signal in the vertical scanning
direction;
at least one horizontal non-correlative energy detection means for
detecting a horizontal non-correlative energy DH from said horizontal
brightness signal non-correlative energy and said horizontal color signal
non-correlative energy;
at least one vertical non-correlative energy detecting means for detecting
a vertical non-correlative energy DV from said vertical brightness signal
non-correlative energy and said vertical color signal non-correlative
energy;
comparative signal generating means for supplying a first comparative
signal to said switching circuit when a first expression DV.gtoreq.m.DH is
satisfied (where m: a predetermined coefficient),
for supplying a second comparative signal when a second expression
DH.gtoreq.n.DV is satisfied (where n: a predetermined coefficient),
and a third comparative signal when neither of the first and second
expressions is satisfied; and
color signal extracting means for controlling said switching circuit so as
to select said first color signal, said second color signal and said third
color signal when the comparative signals received from said comparative
signal generating means are said first comparative signal, said second
comparative signal and said third comparative signal, respectively.
29. The brightness signal/color signal separating filter of claim 28
wherein said horizontal non-correlative energy detecting means includes a
first horizontal non-correlative energy detector detecting a first
horizontal non-correlative energy DHa and a second horizontal
non-correlative energy detector detecting a second horizontal
non-correlative energy DHb, said comparative signal generating means
alternately using Dha and Dhb in each of said first and second
expressions.
30. The brightness signal/color signal separating filter of claim 8 wherein
said vertical non-correlative energy detecting means includes a first
vertical non-correlative energy detector detecting a first vertical
non-correlative energy DVa and a second vertical non-correlative energy
detector detecting a second vertical non-correlative energy DVb, said
comparative signal generating means alternately using Dva and Dvb in each
of said first and second equations.
31. The brightness signal/color signal separating filter of claim 28
wherein said horizontal non-correlative energy detecting means includes a
first horizontal non-correlative energy detector detecting a first
horizontal non-correlative energy Dha and a second horizontal
non-correlative energy detector detecting a second horizontal
non-correlative energy Dhb,
said vertical non-correlative energy detecting means including a first
vertical non-correlative energy detector detecting a first vertical
non-correlative energy Dva and a second vertical non-correlative energy
detector detecting a second vertical non-correlative energy Dvb,
said comparative signal generating means alternately using Dha and Dhb in
each of said first and second equations and further alternately using Dva
and Dvb in each of said equations.
32. The brightness signal/color signal separating filter of claim 28
wherein said means for delaying includes,
a first delay circuit for outputting a first delay composite television
signal generated by delaying the input composite color signal by a
predetermined number of lines;
a second delay circuit for outputting a second delay composite color
television signal generated by further delaying the input composite color
signal delayed by said first delay circuit by an equal number of lines as
delayed in said first delay circuit.
33. A brightness signal/color signal separating filter according to claim
28, wherein said composite video signal is an NTSC (National Television
System Committee) signal.
34. The brightness signal/color signal separating filter of claim 28
further comprising compensating delay means disposed between said
switching circuit and said horiontal, vertical and horizontal/vertical
color signal extracting filters.
35. A brightness signal/color signal separating filter comprising:
means for delaying a composite video signal which is sampled at a frequency
synchronous with a horizontal scanning frequency by one or two lines and
simultaneously extracting the sampled values at the object sampling point
and a plurality of reference sampling points in the vicinity thereof;
a horizontal color signal extracting filter for extracting the frequency
component which corresponds to a color subcarrier frequency component in
the horizontal scanning direction on the basis of the sampled values at
the respective sampling points and outputting the extracted component as a
first color signal;
a vertical color signal extracting filter for extracting the frequency
component which corresponds to a color subcarrier frequency component in
the vertical scanning direction on the basis of the sampled values at the
respective sampling points and outputting the extracted component as a
second color signal;
a horizontal/vertical color signal extracting filter for extracting the
frequency component which corresponds to a color subcarrier frequency
component in the horizontal scanning direction and the vertical scanning
direction on the basis of the sampled values at the respective sampling
points and outputting the extracted component as a third color signal;
a switching circuit for selecting one from said first color signal, said
second color signal and said third color signal and outputting the
selected signal as a separated color signal;
image correlation judging means for outputting a color signal selection
signal by detecting the image correlations in the vertical and horizontal
scanning directions, respectively, from the sampled values of the
respective sampling points; and
a subtracter for subtracting the separated color signal from the sampled
values at the respective sampling points and outputting the signal
obtained as a separated brightness signal;
said image correlation judging means including;
horizontal brightness signal non-correlative energy detecting means for
detecting the correlation strength of the brightness signal in the
horizontal scanning direction from the sampled values at the respective
sampling points;
horizontal color signal non-correlative energy detecting means for
detecting the correlation strength of the color signal in the horizontal
scanning direction;
vertical brightness signal non-correlative energy detecting means for
detecting the correlation strength of the brightness signal in the
vertical scanning direction;
vertical color signal non-correlative energy detecting means for detecting
the correlation strength of the color signal in the vertical scanning
direction;
at least one horizontal non-correlative energy detecting means for
outputting the maximum value of said horizontal brightness signal
non-correlative energy multiplied by an integral number and said
horizontal color signal non-correlative energy multiplied by an integral
number as a horizontal non-correlative energy;
at least one vertical non-correlative energy detecting means for outputting
the maximum value of said vertical brightness signal non-correlative
energy multiplied by an integral number and said vertical color signal
non-correlative energy multiplied by an integral number as a vertical
non-correlative energy;
comparative signal generating means for comparing said vertical
non-correlation energy with said horizontal non-correlation energy and
supplying a first comparative signal to said switching circuit when said
vertical non-correlation energy is judged to be a predetermined amount
greater than said horizontal non-correlation energy, a second comparative
signal when said horizontal non-correlation energy is judged to be a
predetermined amount greater than said vertical non-correlation energy,
and a third comparative signal when neither of the above two conditions
exist; and
color signal extracting means for controlling said switching circuit so as
to select said first color signal, said second color signal and said third
color signal when the comparative signals received from said comparative
signal generating means are said first comparative signal, said second
comparative signal and said third comparative signal, respectively.
36. The brightness signal/color signal separating filter of claim 35
wherein said means for delaying includes,
a first delay circuit for outputting a first delay composite television
signal generated by delaying the input composite color signal by a
predetermined number of lines;
a second delay circuit for outputting a second delay composite color
television signal generated by further delaying the input composite color
signal delayed by first delay circuit by an equal number of lines as
delayed in said first delay circuit.
37. A brightness signal/color signal separating filter according to claim
35, wherein said composite video signal is an NTSC (National Television
System Committee) signal.
38. The brightness signal/color signal separating filter of claim 35
further comprising compensating delay means disposed between said
switching circuit and said horizontal, vertical and horizontal/vertical
color signal extracting filters.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a brightness signal/color signal separating
filter, and more particularly to an improvement thereof which separates
brightness signal and color signal from a composite television signal, of
e.g. NTSC (National Television System Committee) type of PAL (Phase
Alternate Line) type, in dependence upon the magnitude of detected
vertical or horizontal correlative energy of the composite television
signal.
2. Description of the Related Art
FIG. 16 of the accompanying drawings is a block diagram showing an example
of conventional brightness signal/color signal separating filter. In FIG.
16, the numerals respectively designate: 111, an input terminal for
inputting NTSC type composite color television signal: 2, an A/D converter
for converting an analog composite color television signal into a digital
signal; 3 and 4, a first and a second one line delay circuit; 5,
compensating delay circuit; 6, a vertical filter; 7, a band pass filter; 8
and 10, output terminals; and 9, substracting circuit.
In operation, the composite color television signal inputted to the input
terminal 111 enters the A/D converter 2, the output digital signals of
which are supplied to both the first one line delay circuit 3 and the
vertical filter 6.
One output of the first one line delay circuit 3 is directly supplied to
the vertical filter 6, while another output is delayed by one line in the
second one line delay circuit 4 and thereafter supplied to the vertical
filter 6.
The vertical filter 6 is generally referred to as a two line type
comb-shaped filter, the output of which is fed to the band pass filter 7.
The band pass filter 7 outputs color signals 205, one to the output
terminal 8, and another to one input terminal of the subtracting circuit
9. The other input terminal of the subtracting circuit 9 receives the
output of the first one line delay circuit 3 through a compensating delay
circuit 5 which compensates the amount delayed in the band pass filter 7.
The subtracting circuit 9 then outputs a brightness signal 207 to the
output terminal 10.
It will now be explained how the above-mentioned filter functions on the
NTSC type composite color television signal. The input signal 201 of the
composite color television signal having been simultaneously sampled by
the color subcarrier with the sampling frequency fs=4 * fsc (fsc: a color
subcarrier frequency which is approximately 3.58 MHz in NTSC type, while
approximately 4.43 MHz in PAL type) would be displayed in two-dimentional
arrangement on the screen as shown in FIG. 17.
Namely, with fsc=(455/2) * fH (fH: horizontal frequency: approximately 15.7
kHz in NTSC and 15.6 kHz in PAL), the phase of the color signal C inverts
by 180 degrees per line, resulting in 4 samples at each cycle. Here,
assuming that the codes Y and C1, C2 designate brightness signal and color
signals respectively in the drawing, the white circle, the slashed circle,
the white triangle, and the slashed triangle represent Y+C1, Y-C1, Y+C2,
and Y-C2, respectively.
When Z.sup.-1 by Z-conversion is used as a code for representing the delay
by one sample, it would be expressed as Z.sup.-1 =exp (-j 2.pi.f/4 fsc).
Then, a delay by one line Z.sup.-l becomes Z.sup.-l =exp (-j
2.pi.f/fH)=exp (-j 2.pi.fl/4 fsc), resulting in l=910 upon fsc=4 * (455/2)
* FH.
At this time, the vertical filter 3 extracts a line aiding signal 204, for
aiding per each line including the color signal, from the one line delay
signal and the two line delay signal which are delayed by the first and
second one line delay circuit 3 and 4, and from the current input signal
201. The transmission function Hv (Z) of the vertical filter 6 can be
expressed as Hv (Z)=(-1/4) * (1-Z.sup.-l)2.
In other words, the line aiding signal Hc (m, n) at the coordinates (m, n)
on the screen shown in FIG. 17 is sampled as Hc (m, n)=-(1/4) * {S (m,
n-1)-2S (m, n)+S (m, n+1)}. Since the line aiding signal contains the
brightness signal Y too, the color signal C (m, n) being high frequency
component is separated from the line aiding signal Hc (m, n) by the band
pass filter 7. The resulting color signal 205 will be supplied to the
substracting circuit 9.
In this case, the transmission function of the band pass filter 7 can be
composed, for example, as Hh (Z)=(-1/32) * (1-Z.sup.-2).sup.2 *
(1+Z.sup.-4).sup.2 * (1+Z.sup.-8).
The one line delay signal 202 is delayed, in accordance with the delaying
amount of the band pass filter 7, by the compensating delay circuit 5. The
subtracting circuit 9 substracts the color signal C (m, n) from the signal
S (m, n), and thereby extracts the brightness signal Y (m, n) as Y (m,
n)=S (m, n)-C (m, n).
As described above, in the conventional brightness signal/color signal
separating filter, the characteristics of the vertical filter and the
horizontal filter have been fixedly combined. Namely, the brightness
signal/color signal separating process has been performed, in both the
vertical and the horizontal directions, by a band pass filter.
Consequently, in regions where the brightness and the color of the image
greatly change, the brightness signal and the color signal have mutually
leaked into the other's channel, causing a degraded reproductive image by
e.g. dot interference.
SUMMARY OF THE INVENTION
It is therefore an object of this invention to provide a brightness
signal/color signal separating filter which is capable of accurately
separating a brightness signal and a color signal from a composite color
television signal of e.g. NTSC type or PAL type, even when intensive
change in brightness and color of an image takes place.
According to this invention, a brightness signal/color signal separating
filter for separating the brightness signal and color signal from
composite color television signal, comprises:
a first delay circuit for outputting a first delay composite television
signal generated by delaying an input composite color signal by a
predetermined number of lines;
a second delay circuit for outputting a second delay composite color
television signal generated by further delaying the composite color signal
delayed by said first delay circuit by the same number of lines as in said
first delay circuit;
a vertical color signal extracting filter for extracting vertical color
signal from the input composite color television signal, first delay
composite color television signal, and second delay composite color
television signal;
a horizontal color signal extracting filter for extracting horizontal color
signal from the first delay composite color television signal;
a horizontal/vertical color signal extracting filter for extracting
horizontal and vertical color signals from said input, first delay and
second delay composite color television signals;
a switching circuit for selectively outputting any one of outputs from said
vertical color signal extracting filter, horizontal color signal
extracting filter, and horizontal/vertical color signal extracting filter;
and
an image correlation judging circuit for comparatively judging correlation
of an image by said input first delay and second delay composite color
television signals in the vertical and horizontal directions, and for
outputting horizontal color signal when the horizontal correlation is
strong, for outputting vertical color signal when vertical correlation is
strong and the horizontal correlation is weak, and for outputting both
horizontal and vertical color signals when both the horizontal and
vertical correlations are weak, respectively, from said switching circuit;
said image correlation judging circuit including:
a) a non-correlative energy extracting circuit for extracting horizontal
color signal non-correlative energy representative of correlative strength
of the horizontal color signal, horizontal brightness signal
non-correlative energy representative of correlative strength of the
horizontal brightness signal, vertical color signal non-correlative energy
representative of correlative strength of the vertical color signal, and
vertical brightness signal non-correlative energy representative of
correlative strength of the vertical brightness signal;
b) comparative signal generating means for generating four comparative
signals representative of vertical and horizontal correlative strength of
the composite color television signal, one based on horizontal color
signal non-correlative energy, horizontal brightness signal
non-correlative energy, vertical color signal non-correlative energy, and
vertical brightness signal non-correlative energy, respectively;
c) comparative judging means for comparatively judging the horizontal and
vertical correlative strengths of the composite color television signal,
and for ordering said switching circuit to output horizontal color signal
extracted by the horizontal color signal extracting circuit when the
horizontal correlation is strong vertical color signal extracted by the
vertical color signal extracting filter when vertical correlation is
stronger than horizontal correlation, and horizontal/vertical color
signals extracted by the horizontal/vertical color signal extracting
filter when both the horizontal and vertical correlations are weak.
In the brightness signal/color signal separating filter of this invention
mentioned above, composite color television signals of NTSC type or PAL
type are sequentially delayed in the first delay circuit and the second
delay circuit by a predetermined number of lines. The numbers of lines for
delaying process in the first delay circuit and the second delay circuit
are identical. Namely, on the basis of the first delayed composite color
television signal obtained by the first delay circuit, the composite color
television signal on the screen, before being delayed, is displayed prior
to the composite color television signal delayed by the first delay
circuit by a predetermined number of lines, and the composite color
television signal delayed by the second delay circuit is displayed after
the composite color television signal delayed by the first delay circuit
by the same number of lines.
These three kinds of composite color television signals are then supplied
to the vertical color signal extracting filter and the horizontal/vertical
color signal extracting filter. Particularly the first delayed composite
color television signal is additionally supplied to the horizontal color
signal extracting filter.
The vertical color signal extracting filter extracts vertical color signal.
In this case, "vertical" means the direction perpendicular to the lines.
Therefore, the three types of composite color television signals are
necessary for the extraction of the vertical color signal by the vertical
color signal extracting filter.
The horizontal color signal extracting filter extracts horizontal color
signal. In this circuit, among the three types of composite color
television signals, only the one corresponding to the intermediate line
i.e. the composite color television signal delayed by the first delay
circuit is used, since a signal which belongs to an identical line will
suffice.
The horizontal/vertical color signal extracting filter extracts color
signals in the vertical and horizontal directions.
The color signals extracted by these three types of filters are then
supplied to the switching circuit. The switching circuit selectively
outputs any of the color signal depending on the result of a comparative
judgement carried out in the image correlation judging circuit. The image
correlation judging circuit lets the switching circuit selectively output:
the horizontal color signal when horizontal correlation is strong; the
vertical color signal when the horizontal correlation is weak and the
vertical correlation is strong; and vertical and horizontal color signals
when both the horizontal and vertical correlations are weak.
As a result, even when there is intensive color etc. changes arising in
composite color television signals, it is possible to output color signals
surely separated on the basis of the correlative judgment result.
A further significant feature of this invention lies in the composition and
the function of the image correlation judging circuit.
The image correlation judging circuit performs the correlation judgment and
controls the switching circuit in the following order of procedure:
extraction of non-correlative energy--generation of comparative
signal--comparative analysis based on the comparative signal.
For a start, the non-correlative energy extracting means extracts
horizontal color signal non-correlative energy, horizontal brightness
signal non-correlative energy, vertical color signal non-correlative
energy, and vertical brightness signal non-correlative energy,
representative of the weakness of the horizontal color signal, the
horizontal brightness signal, vertical color signal non-correlative
energy, and the vertical brightness signal, respectively, from the
aforementioned three types of delayed composite color television signals.
Next, first through fourth comparative signals, representative of
horizontal or vertical correlative weaknesses, are generated on the basis
of the energies.
Accordingly, horizontal and vertical correlative weaknesses of the
composite color television signal can be judged from the comparative
signal.
There are four types of non-correlative energies depending on the subject
signal being horizontal signal or vertical signal, and color signal or
brightness signal. So there may be provided a non-correlative energy
extracting means comprising four types of non-correlative energy
extracting circuits: a horizontal color signal non-correlative energy
extracting circuit; a horizontal brightness signal non-correlative energy
extracting circuit; a vertical color signal non-correlative energy
extracting circuit; and a vertical brightness signal non-correlative
energy extracting circuit. Each of such circuits is preferably composed of
FIR (finite impulse response) filter, or of course, IIR (infinite impulse
response filter).
A FIR filter can be composed of each of a predetermined number of delay
means, subtracting means, absolute value calculating means, filters, and
maximum value calculating means. The comparative judging means, for
comparatively judging the comparative signals, may be composed of a
comparing circuit and a judging circuit. As a comparing circuit, a typical
two signal-comparing-type circuit may be used. In this case, first and
second comparing circuits are required, since four types of comparative
signals appear. The judging circuit determines the subject to be
controlled in the switching circuit, and performs the controlling
operation. The judging circuit, when the output of the comparing circuit
is a binary signal, can be a logical element of NOT, AND, etc..
A comparative signal can be generated by the combination of a multiplier,
an adder, and a maximum value circuit.
The horizontal color signal non-correlative energy extracting circuit
and/or the vertical color signal non-correlative energy extracting circuit
can be twice.
The above and other advantages, features and additional objects of this
invention will be manifest to those versed in the art upon making
reference to the following detailed description and the accompanying
drawings in which a structural embodiment incorporating the principles of
this invention is shown by way of illustrative example.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram showing a brightness signal/color signal
separating filter according to the first embodiment of this invention;
FIG. 2 is a detail block diagram of the image correlation judging circuit
in FIG. 1;
FIG. 3 is a detail block diagram of the judging circuit in FIG. 2;
FIG. 4 is a detail block diagram of the horizontal color signal
non-correlative energy extracting circuit in FIG. 1;
FIG. 5 is a detail block diagram of the horizontal brightness signal
non-correlative energy extracting circuit in FIG. 1;
FIG. 6 is a detail block diagram of the vertical color signal
non-correlative energy extracting circuit in FIG. 1;
FIG. 7 is a detail block diagram of the vertical brightness signal
non-correlative energy extracting circuit in FIG. 1;
FIG. 8 is a block diagram of an image correlation judging circuit according
to the third embodiment;
FIG. 9 is a block diagram of an image correlation judging circuit according
to the third embodiment;
FIG. 10 is a block diagram of an image correlation judging circuit
according to the fourth embodiment;
FIG. 11 is a block diagram of an image correlation judging circuit
according to the fifth embodiment;
FIG. 12 is a block diagram of an image correlation judging circuit
according to the sixth embodiment;
FIG. 13 is a block diagram of an image correlation judging circuit
according to the seventh embodiment;
FIG. 14 is a block diagram of an image correlation judging circuit
according to the eighth embodiment;
FIG. 15 is a block diagram of an color signal/brightness signal separating
filter according to the second embodiment, for separating the composite
color television signal of PAL type;
FIG. 16 is a block diagram showing a conventional brightness signal/color
signal separating filter;
FIG. 17 illustrates an arrangement of signal successions on the screen;
FIG. 18 is a block diagram of an image correlation judging circuit
according to the ninth embodiment;
FIG. 19 is a block diagram of an image correlation judging circuit
according to the tenth embodiment.
DETAILED DESCRIPTION
The principles of this invention are particularly useful when embodied in a
brightness signal/color signal separating filter such as shown in FIG. 1.
In FIG. 1, of an NTSC type circuit, an NTSC type composite color television
signal is supplied to the input terminal 11. An A/D converter 12 converts
the composite color television signal supplied through the input terminal
11 into digital signal. A first delay circuit 13 delays the output signal
101 of the A/D converter 12 by one line, and a second delay circuit 14
further delays that signal by another one line. The compensating delay
circuit 15 compensationally delays the output signal 102 of the first
delay circuit 13. The output signals 101, 102, and 103 of the A/D
converter 12, the first delay circuit 13, and the second delay circuit 14,
are fed to a vertical color signal extracting filter 16, a
horizontal/vertical color signal extracting filter 17, and the image
correlation judging circuit 18, respectively. The output signal 102 of the
first delay circuit 13 is additionally supplied to a horizontal color
signal extracting filter 19. The output signal 104 of the vertical color
signal extracting filter 16 is supplied to the compensating delay circuit
20, and likewise: the output signal 108 of the horizontal/vertical color
signal extracting filter 17, to the compensating delay circuit 21; the
output signal 106 of the horizontal color signal extracting filter 19, to
the compensating delay circuit 22, respectively. The switching circuit
selects any one of the output signals 105, 107, and 109 of the
compensating delay circuit 20, 22, and 21, based on the supplied output
signal 110 of the image correlation judging circuit 1. The signal
outputted from the output terminal 24 of the switching circuit 23 is a
color signal. Meanwhile, the difference between the output signal 112 of
the compensating delay circuit 15 and the output signal 111 of the
switching circuit 23, obtained by the subtracting circuit 25, is outputted
from the output terminal 26 as a brightness signal 113.
In FIG. 2, the numbers designate respectively: 1127, a horizontal color
signal non-correlative energy extracting circuit; 1128, horizontal
brightness signal non-correlative energy extracting circuit; 1129,
vertical color signal non-correlative energy extracting circuit; 1130,
vertical brightness signal non-correlative energy extracting circuit;
1139, 1140, 1141, 1142, maximum value circuits; 1131-1138, 1143, 1144,
multiplier circuits; 1145, 1146 comparative circuits; 1147, judging
circuit; 1148, color signal extraction controlling circuit.
The output signal 101 of the A/D signal 12 is supplied to the horizontal
brightness signal non-correlative energy extracting circuit 1128, the
vertical color signal non-correlative energy extracting circuit 1129 and
the vertical brightness signal non-correlative energy extracting circuit
1130.
The output signal 102 of the first delay circuit 13 is supplied to the
horizontal color signal non-correlative energy extracting circuit 1127,
the horizontal brightness signal non-correlative energy extracting circuit
1128, and the vertical brightness signal non-correlative energy extracting
circuit 1130.
The output signal 103 of the second delay circuit 14 is supplied to the
horizontal brightness signal non-correlative energy extracting circuit
1128, vertical color signal non-correlative energy extracting circuit
1129, and the vertical brightness signal non-correlative energy extracting
circuit 1130.
The output signal DCH of the horizontal color signal non-correlative energy
extracting circuit 1127 is supplied to the multiplier 1131, 37. The
multiplying circuit 1137 multiplies the signal DCH by a constant K9 and
supplies the multiplied result to the maximum value circuit 1140, while
the multiplying circuit 1131 multiplies the signal DCH by a constant K1
and supplies the multiplied result to the maximum value circuit 1139. The
output signal DYH of the horizontal brightness signal non-correlative
energy extracting circuit 1128 is supplied to the multiplying circuit
1132, 1138. The multiplying circuit 1138 multiplies the signal DYH by a
constant K10 and supplies the multiplied result to the maximum value
circuit 1140, while the multiplying circuit 1132 multiplies the signal DYH
by a constant K2 and supplies the multiplied result to the maximum value
circuit 1139. The output signal of the maximum value circuit 1139 is then
supplied to the comparing circuit 1145 as first horizontal non-correlative
energy DH1. The output signal of the maximum value circuit 1140 is, after
multiplied by a constant K5 in the multiplying circuit 1143, supplied to
the comparing circuit 1145 as second horizontal non-correlative energy
DH2.
The output signal DCV of the vertical color signal non-correlative energy
extracting circuit 1129 is supplied to the multiplying circuit 1135, 1133.
The multiplying circuit 1135 multiplies the signal DCV by a constant K7
and supplies the multiplied result to the maximum value circuit 1141,
while the multiplying circuit 1133 multiplies the signal DCV by a constant
K3 and supplies the multiplied result to the maximum value circuit 1142.
The output signal DYV of the vertical brightness signal non-correlative
energy extracting circuit 1130 is supplied to the multiplying circuit
1136, 34. The multiplying circuit 1136 multiplies the signal DYV by a
constant K8 and supplies the multiplied result to the maximum value
circuit 1141, while the multiplying circuit 1134 multiplies the signal DYV
by a constant K4 and supplies the multiplied result to the maximum value
circuit 1142. The output signal of the maximum value circuit 1142 is
supplied to the comparing circuit 1146 as first non-correlative energy
DV1. The output signal of the maximum value circuit 1141 is, after
multiplied by a constant K6, to the comparing circuit 1145 of the color
signal extraction controlling circuit 1148 as second vertical
non-correlative energy DV2.
The comparing circuit 1145 compares the first horizontal non-correlative
energy DH1 with the product K6 * DV2 of the second vertical
non-correlative energy DV2 multiplied by a constant K6, and makes the
output signal 115 HIGH level in case of DH1.gtoreq.K6 * DV2 and LOW level
in other cases.
The comparing circuit 1146 compares the first vertical non-correlative
energy DV1 with the product K5 * DHd2 of the second horizontal
non-correlative energy DH2 multiplied by a constant K5, and makes the
output signal 114 HIGH level in case of DV1.gtoreq.K5 * DH2 and LOW level
in other cases.
The output signals 115 and 114 of the comparing circuit 1145 and 1146
respectively are supplied to the judging circuit 1147 of the color signal
extraction controlling circuit 1148. The output signal 110 of the judging
circuit 1147 is sent out as an output of the image correlation judging
circuit.
FIG. 3 is a circuit diagram showing an exemplified judging circuit 1147 in
FIG. 2. This judging circuit 1147 is composed of an AND circuit 48, 49, a
NOT circuit 50, 51. The output signal 115 of the comparing circuit 1145 is
inputted to an input terminal of the AND circuit 49 through the NOT
circuit. The output signal 114 of the comparing circuit 1146 is inputted
to the AND circuit 48, 49 through the NOT circuit. The output signals of
the AND circuit 48, 49 becomes an output signal 110 of the image
correlation judging circuit.
FIG. 4 is a block diagram, showing an exemplified horizontal color signal
non-correlative energy extracting circuit 1127 in FIG. 2., including a
delay circuit 52, a subtracting circuit 53 and an absolute value circuit
54.
The output signal 102 of the first delay circuit 13 is fed to an input
terminal of the delay circuit 52 having a delaying amount equivalent to
one cycle of color subcarrier [=(1/fsc)].
The output signal 102 of the first delay circuit 13 and the output signal
of the delay circuit 52 are supplied to the subtracting circuit 53. The
output signal of the subtracting circuit 53 i.e. the difference between
the both supplied signals are fed to the absolute value circuit 54, the
output DCH of which becomes an output of the horizontal color signal
non-correlative energy extracting circuit 1127.
FIG. 5 is a block diagram showing an exemplified horizontal brightness
signal non-correlative energy extracting circuit 1128 in FIG. 2 including
a vertical low pass filter 55, a first delay circuit 56, a second delay
circuit 57, a first subtracting circuit 58, a second subtracting circuit
59, a first absolute value circuit 60, a second absolute value circuit 61,
and a maximum value circuit 62.
The output signals 101, 102, and 103 of the A/D converter 12, the first
delay circuit 13 and the second delay circuit 14 respectively, are
inputted to the vertical low pass filter.
The output signal of the vertical low pass filter in FIG. 5 is supplied to
the first delay circuit 56 having a delaying amount corresponding to a
half of the cycle of color subcarrier, and thereafter, further supplied to
the first subtracting circuit 58 along with the output of the first delay
circuit 56. On the other side, the output of the first delay circuit 56 is
fed to the input terminals of the second delay circuit 57 and the second
subtracting circuit 59. The output of the delay circuit 57 is also
supplied to the second subtracting circuit 59. The outputs of the first
subtracting circuit 58 are sequentially inputted to the maximum value
circuit through the first absolute value circuit 60, while the output of
the second subtracting circuit 59 is inputted to the maximum value circuit
62 through the second absolute value circuit 61. The output DYH of the
maximum value circuit 62 becomes an output of the horizontal brightness
signal non-correlative energy extracting circuit 1128.
FIG. 6 is a block diagram showing an exemplified vertical color signal
non-correlative energy extracting circuit 1129 in FIG. 2 including a first
and a second horizontal band pass filters 63, 64, a subtracting circuit
65, and a absolute valve circuit 66.
The output signal 101 of the A/D converter 12 is supplied to the first
horizontal band pass filter 63, and the output signal 103 of the second
delay circuit 14 is supplied to the second horizontal band pass filter 64.
The outputs of the first and second horizontal band pass filters 63, 64
are supplied to the subtracting circuit 65, the output of which is then
inputted to the absolute value circuit 66. The output DCV of the maximum
value circuit 66 becomes an output of the vertical color signal
non-correlative energy extracting circuit 1129.
FIG. 7 is a circuit diagram showing an exemplified vertical brightness
signal non-correlative energy extracting circuit in FIG. 2 including a
first through a third horizontal low pass filters 67-69, a first and a
second substracting circuits 70, 71, a first and a second absolute value
circuits 72, 73 and a maximum value circuit 74.
The output signal 101 of the A/D converter 12 is inputted to the horizontal
low pass filter 67, and likewise: the output signal 102 of the first delay
circuit 13, to the horizontal low pass filter 68; the output signal 103 of
the second delay circuit 14, to the horizontal low pass filter 69; the
output of the first horizontal low pass filter 67, to the first
subtracting circuit 70; the output of the second horizontal low pass
filter 68, to the first and the second subtracting circuits 70, 71; the
output of the third horizontal low pass filter 69, to the second
subtracting circuit 71.
The outputs of the first and the second subtracting circuits 70 and 71 are
supplied to the first and the second absolute value circuits 72 and 73
respectively, and the outputs of the first and the second absolute value
circuits 72, 73 are supplied to the maximum value circuit 74. The output
DYV of this absolute value circuit 74 becomes the output of the vertical
brightness signal non-correlative energy extracting circuit 1130.
In operation, when a NTSC type composite color television signal is input
via the input terminal 11, the A/D converter 12 samples this signal with
the sampling frequency fs=4fsc.
The output signal 101 of the A/D converter 12 represents a sampling value
at a target sampling point, and renders a sampling value at a position
upper by one line on screen when inputted to the first delay circuit 13
and a sampling value at a position lower by one line on the screen when
inputted to the second delay circuit 14.
Namely, signals S (m, n-1) and S (m, n=1) appear at the outputs of the
second delay circuit 14 and the A/D converter 12 respectively when a
composite color television signal (sampling value) S (m, n) is outputted
from the first delay circuit 13 (see FIG. 17). The brightness signal/color
signal separating filter is designed on the basis of these sampling values
at the sampling points over three lines on the screen.
The both sampling values outputted from the first and the second delay
circuits 13 and 14 are supplied to the vertical color signal extracting
filter 16, the horizontal/vertical color signal extracting filter 17, the
image correlation judging circuit 1. The sampling value from the first
delay circuit 13 is additionally supplied to the horizontal color signal
extracting filter 19.
In this case, the transmitting functions of the vertical color signal
extracting filter 16, the horizontal color signal extracting filter 19,
and the horizontal/vertical color signal extracting filter 17 are can be
expressed respectively e.g.:
Cv(Z)=(-1/4)(1-Z.sup.-l).sup.2
Ch(Z)=(-1/4)(1-Z.sup.-2).sup.2
Chv(Z)=(-1/4)(1-Z.sup.-2).sup.2 *(-1/4)(1-Z.sup.-l).sup.2
The output signals 104, 106 and 108 of these filters 16, 19 and 17 are
compensating-delayed respectively in the compensating delay circuit 20, 22
and 21, and thereafter inputted to the switching circuit 23 as signals
105, 107 and 109.
The switching circuit 23 selects any one of the color output signals from
the vertical color signal extracting filter 16, horizontal color signal
extracting filter 19, and the horizontal/vertical color signal extracting
filter 17.
This selection is carried out on the following basis. Firstly, the image
correlation judging circuit 1 detects the vertical and horizontal image
correlations on the target sampling point. Based on the detected result,
the switching circuit 23 is switched upon receiving the signal 110 to
select: the output signal 105 of the compensating delay circuit 20 when
the vertical correlation is particularly strong; the output signal 107 of
the compensating circuit 22 when the horizontal correlation is
particularly strong; and the output signal 109 of the compensating delay
circuit 21 in other cases.
The image correlation judging circuit 1 controls the switching circuit 23
in the manner as described hereinafter.
A transmission function DCH (Z) of the horizontal color signal
non-correlative energy extracting circuit 1127, likewise DYH (Z) of the
horizontal brightness signal non-correlative energy extracting circuit
1128, DCV (Z) of the vertical color signal non-correlative energy
extracting circuit 1129, and DYV (Z) of the vertical brightness signal
non-correlative energy extracting circuit 1130 can be expressed, from the
composition of the circuit 1127-1130, as:
DCH(Z)=.vertline.1-Z.sup.-4 .vertline.
DYH(Z)=max (.vertline.(1/4)*(1+Z.sup.-l).sup.2 *(1-Z.sup.-2),
.vertline.(1/4)*(1+Z.sup.-l).sup.2 (Z.sup.-2 -Z.sup.-4).vertline.)
DCV(Z)=.vertline.(1-Z.sup.-2).sup.2 *(1-Z.sup.-2l).vertline.
DYV(Z)=max (.vertline.(1/4)*(1+Z.sup.-2).sup.2 *(1-Z.sup.-l).vertline.,
.vertline.(1/4)*(1+Z.sup.-2).sup.2 *(Z.sup.-l -Z.sup.-2l).vertline.)
The output DCH, DYH, DCV, and DYV of the circuits 1127-1130 having these
transmission functions are as mentioned above supplied to the maximum
value circuits 1139-1142 through the multipliers 1131-1138. As a result,
generated first horizontal non-correlative energy DH1, second horizontal
non-correlative energy DH2, first vertical non-correlative energy DV1, and
second vertical non-correlative energy DV2 are expressed as follows:
DH1=max (K1*DCH, K2*DYH)
DH2=max (K9*KCH, K10*DYH)
DV1=max (K3*DCV, K4*DYV)
DV2=max (K7*DCV, K8*DYV)
At this time, the comparing circuit 1146 of the image correlation judging
circuit 1, if DV1.gtoreq.K5 * DH2, outputs signal "1" to the judging
circuit 1147 regarding that there is horizontal correlation without any
vertical correlation; and if DV1<K5 * DH2, outputs signal "0" to the
judging circuit 1147 regarding that there is no horizontal correlation.
On the other hand, the comparing circuit 1145 of the image correlation
judging circuit 1, if DH1.gtoreq.K6*DV2, outputs a signal "1" to the
judging circuit 1147 regarding that there is vertical correlation without
any horizontal correlation; and if DHd1<K6 * DV2, outputs a signal "0" to
the judging circuit 1147 regarding that there is no vertical correlation.
The judging circuit 1147 controls the switching circuit 23 according to the
detected result of above correlation, namely, the relationship between the
input and the output of the judging circuit 1147 becomes as the TABLE 1.
TABLE 1
__________________________________________________________________________
output signals of:
110 of the
judging circuit
1147
114 of the
115 of the
110a of
110b of
comparing
comparing
the AND
the AND
111 selected by
circuit
circuit
circuit
circuit
the switching
1146 1145 48 49 circuit 23
__________________________________________________________________________
for H/V
0 0 0 1 109
extraction
for V extrac-
0 1 1 0 105
tion
1 0 0 0 107
for H
1 1 0 0 107
extraction
__________________________________________________________________________
(H: horizontal)
(V: vertical)
The switching circuit 23 is switched in response to these outputs of the
AND circuits 48 and 49: the output signal 107 of the compensating delay
circuit 22 is passed when the both output signals of the AND circuits 48
and 49 are "0"; the output signal 105 of the compensating delay circuit 20
is passed when the output signal of the AND circuit 48 is "1" and the
output signal of the AND circuit 49 is "0"; the output signal 109 of the
compensating delay circuit 21 is passed when the output signal of the AND
circuit 48 is "0" and the output signal of the AND circuit 49 is "1".
Thus, in the embodiment shown in FIG. 1, the color signal extracting filter
characteristic C (Z) becomes switched, according to whether the
correlation exists or not, as follows:
C(Z)=Ch(Z),
when there is horizontal correlation;
C(Z)=Cv(Z),
when there is no horizontal correlation, and no vertical correlation; and
C(Z)=Chv(Z),
when there is neither horizontal correlation nor vertical correlation.
In this manner, according to this embodiment, the vertical and horizontal
image correlations of a composite color television signal are detected by
the image correlation judging circuit 1 and that the switching circuit 23
is switched in response to the detected result. Consequently, mutual
leakage of the brightness signal and the color signal into another's
channel can be reduced, thereby avoiding dot jamming.
FIG. 8 shows an image correlation judging circuit of the brightness
signal/color signal separating filter according to the second embodiment
of this invention.
In this embodiment, the horizontal non-correlative energy extracting
circuit 1227 is divided into sub/circuits 1227a and 1227b having mutually
different property. Further, the vertical color signal non-correlative
energy extracting circuit 1229 is divided into sub-circuits 1229a and
1229b in the same manner. The horizontal color signal non-correlative
energy extracting circuit 1227a supplies the DCH1 to the multiplier 1231,
while the horizontal color signal non-correlative energy extracting
circuit 1227b supplies the DCH2 to the multiplier 1237, respectively.
Likewise, the vertical color signal non-correlative energy extracting
circuit 1229a supplies the DCV1 to the multiplier 1235, while the vertical
color signal non-correlative energy extracting circuit 1229b supplies DCV2
to the multiplier 1233, respectively.
Also in such composition, the similar effect to the first embodiment can be
rendered.
Alternatively, it is also possible to divide each of the horizontal
brightness signal non-correlative energy extracting circuit 1228, the
vertical brightness signal non-correlative energy extracting circuit 1230
into two sub-circuits of mutually different properties.
FIG. 9 shows an image correlation judging circuit 1 of the brightness
signal/color signal separating filter according to the third embodiment of
this invention.
This embodiment incorporates an adder 1375 for adding the output DCH of the
horizontal color signal non-correlative energy extracting circuit 1327 to
the output DYH of the horizontal brightness signal non-correlative energy
extracting circuit 1328, and likewise, an adder 1376 for adding the output
DCV of the vertical color signal non-correlative energy extracting circuit
1329 to the output DYV of the vertical brightness signal extracting
circuit 1330.
The adder 1375 is connected to the comparing circuit 1346 of the color
signal extraction controlling circuit 1348 via the multiplier 1377. The
multiplier 1377 multiplies the output DH1 of an integer m, and supplies
the multiplied result m * DH1 to the comparing circuit 1346. The output
DH1 of the adder 1375 is additionally supplied to the comparing circuit
1345 of the color signal extraction controlling circuit 1348.
Similarly, the adder 1376 is connected to the comparing circuit 1345
through the multiplier 1378. The adder 1378 multiplies the output DV1 of
the multiplier 1376 by an integer n, and supplies the multiplied result n
* DV1 to the comparing circuit 1345. The output DV1 of the multiplier 1376
is additionally supplied to the comparing circuit 1346 of the color signal
extraction controlling circuit 1348.
The comparing circuit 1346 compares the magnitude of m * DH1 with DV1, and
makes the output signal 114 high level in case of DV1.gtoreq.m * DH1 and
makes that low level in remaining cases.
Similarly, the comparing circuit 1345 compares n * DV1 with DH1, and makes
the output signal 115 high level when DH1.gtoreq.n * DV1 and makes that
low level in remaining cases.
In this embodiment, the outputs of the adder 1375 and the 1376, i.e.
horizontal non-correlative energy DH1 and vertical non-correlative energy
DV1 respectively, can be expressed as:
DH1=DCH+DYH
DV1=DCV+DYV
The comparing circuit 1346 compares DV1 with m * DH1. In case of
DV1.gtoreq.m * DH1, this circuit 1346 judges that there is horizontal
correlation and no vertical correlation and outputs high level signal 114
to the judging circuit 1347, and contrastingly in case of DV1<m * DH 1,
judges that there is no horizontal correlation and outputs low level
signal 114 to the judging circuit 1347.
Similarly, the comparing circuit 1345, in case of DH1.gtoreq.n * DV1,
judges that there is vertical correlation and no horizontal correlation
and outputs high level signal 115 to the judging circuit 1347. Further,
contrastingly in the case of DV1<n * DV1, it judges that there is no
vertical correlation and outputs low level signal 115 to the judging
circuit 1347.
The judging circuit 1347 judges and controls the switching circuit 23
according to the signals 114 and 115. In consequence, the color signal to
be selected will be as shown in the TABLE 1.
Thus, this embodiment can also render the same effect as in the first
embodiment.
FIG. 10 shows a image correlation judging circuit 1 of the brightness
signal/color signal separating filter according to the fourth embodiment
of this invention.
In this embodiment, the output DCH of the horizontal color signal
non-correlative energy extracting circuit 1427 is multiplied by an integer
b in a multiplier 1437 and then supplied to a maximum value circuit 1440.
Likewise, the output DYH of the horizontal brightness signal
non-correlative energy extracting circuit 1428 is multiplied by an integer
a in a multiplier 1438 and then supplied to the maximum value circuit
1440. The maximum value circuit 1440 compares b * DCH with a * DYH for the
maximum value and outputs this as a second horizontal non-correlative
energy DH2. This is in turn multiplied by and integer m in the multiplier
1443 and supplied thereafter to the comparing circuit 1446 of the color
signal extraction controlling circuit 1448.
Similarly, the output DCV of the vertical color signal non-correlative
energy extracting circuit 1429 is multiplied by an integer d in the
multiplier 1435 and then supplied to a maximum value circuit 1441.
Likewise, the output DYV of the vertical brightness signal non-correlative
energy extracting circuit 1430 is multiplied by an integer c in a
multiplier 1436 and then supplied to a maximum value circuit 1441. The
maximum value circuit 1441 compares d * DCV with c * DYV for the maximum
value and outputs this as a second vertical non-correlative energy DV2,
which is multiplied by an integer n in the multiplier 1444 and supplied
thereafter to the comparing circuit 1445 of the color signal extraction
controlling circuit 1448.
Besides the m * DH2, also the first vertical non-correlative energy DV1 is
supplied to the comparing circuit 1446. This energy DV1 has been obtained
by adding the output DCV of the vertical color signal non-correlative
energy extracting circuit 1429 to the output DYV of the vertical
brightness signal non-correlative energy extracting circuit 1430 in the
adder 1476.
Similarly, besides the n * DV2, the first horizontal non-correlative energy
DH1 is also supplied to the comparing circuit 1445. This energy DH1 has
been obtained by adding the output DCH of the horizontal color signal
non-correlative energy extracting circuit 1427 to the output DYH of the
horizontal brightness signal non-correlative energy extracting circuit
1428 in the adder 1475.
The comparing circuits 1446 and 1445 performs a comparing operation similar
to that in the third embodiment, and the judging circuit 1447 of the color
signal extraction controlling circuit 1448 also functions likewise. Here,
the relationship between the signals can be formulated as follows:
DH1=DCH+DYH
DH2=max (b*DCH, a*DYH)
DV1=DCV+DYV
DV2=max (d*DCV, c*DYV)
With these formulas, too, the switching circuit 23 carries out the same
selecting operation as in the first embodiment.
Accordingly, this embodiment can also render similar effect to the first
embodiment.
FIG. 11 shows an image correlation judging circuit 1 of the brightness
signal/color signal separating circuit according to the fifth embodiment
of this invention.
In this embodiment, the output DCH of the horizontal color signal
non-correlative energy extracting circuit 1527 is, after being multiplied
by an integer b in a multiplier 1537, supplied to the maximum value
circuit 1540, and after being multiplied by an integer f in the multiplier
1531, supplied to the maximum value circuit 1539. Likewise, the output DYH
of the horizontal brightness signal non-correlative energy extracting
circuit 1528 is, after being multiplied by the integer a, supplied to the
maximum value circuit 1540, and after being multiplied by an integer e,
supplied to the maximum value circuit 1539.
Similarly, the output DCV of the vertical color signal non-correlative
energy extracting circuit 1529, after multiplied by an integer h in the
being multiplier 1533, is supplied to the adder 1576, and after being
multiplied by an integer d in the multiplier 1535, is supplied to the
maximum value circuit 1541. Likewise, the output DYV of the vertical
brightness signal non-correlative energy extracting circuit 1530, after
being multiplied by an integer g in the multiplier 1534, is supplied to
the adder 1576, and after being multiplied by an integer c, is supplied to
the maximum value circuit 1541.
The maximum value circuit 1540 compares the b * DCH with the a * DYH, and
selects and outputs the larger one to the comparing circuit 1546 as second
horizontal non-correlative energy DH2.
The maximum value circuit 1539 compares the f * DCH with the e * DYH and
outputs the result as third horizontal non-correlative energy DH3. This in
turn, is supplied to the comparing circuit 1545 of the color signal
extraction controlling circuit 1548 after being multiplied by an integer m
in the multiplier 1544.
The adder 1576 adds the h * DCV to the g * DYV and outputs the added result
as a third vertical non-correlative energy DV3, which is supplied to the
comparing circuit 1546 of the color signal extraction controlling circuit
1548 after being multiplied by an integer n in the multiplier 1545.
The maximum value circuit 1541 compares the d * DCV with the c * DYV, and
selects and outputs the larger one to the comparing circuit 1545 as second
vertical non-correlative energy DV2.
The comparing circuit 1546 compares the DH2 with the n * DV3, and, if
DH2.gtoreq.n * DV3, it outputs a high level signal 115 to the judging
circuit 1547 of the color signal extraction controlling circuit 1548
indicating that there is vertical correlation and no horizontal
correlation; and contrastingly, if DH2<n * DV3, it outputs a low level
signal 11 to the judging circuit 1547 indicating that there is no vertical
correlation.
Similarly, the comparing circuit 1545 compares the DV2 with the m * DH3,
and, if DV2.gtoreq.m * DH3, it outputs a high level signal 114 to the
judging circuit 1547 indicating that there is horizontal correlation and
no vertical correlation; and contrastingly, if DV2.ltoreq.m * DH3, it
outputs low level signal 114 to the judging circuit 114 indicating that
there is no horizontal correlation. The judging circuit 114 operates in
same manner as the aforementioned fourth embodiment.
Accordingly, also in this embodiment, the switching circuit 23 functions
according to the TABLE 1 and similar effect can be rendered.
FIG. 12 shows an image correlation judging circuit 1 of the brightness
signal/color signal separating filter according to the sixth embodiment of
this invention.
This embodiment differs from the fifth embodiment in that the maximum value
circuit 1539 in the fifth embodiment is replaced by an adder 1675, and the
adder 1576 in the fifth embodiment is replaced by a maximum value circuit
1642. Also the same effect can be obtained by this embodiment.
FIG. 13 shows an image correlation judging circuit 1 of the brightness
signal/color signal separating filter according to a seventh embodiment of
this invention.
This embodiment features to dividedly compose the horizontal color signal
non-correlative energy extracting circuit 1527 and the vertical color
signal non-correlative energy extracting circuit 1529 respectively into
two subcircuits having mutually different characteristics.
Among the two sub-circuits of the horizontal color signal non-correlative
energy extracting circuit 1727, the one 1727a supplies the output DCH1 to
the maximum value circuit 1740, and the other 1727b supplies the output
DCH2 to the maximum value circuit 1739. Similarly, the one sub-circuit
1729a of the vertical color signal non-correlative energy extracting
circuit 1729 supplies the output DCV1 to the maximum value circuit 1741,
and the other 1729b supplies the output DCV2 to the adder 1776.
The switching circuit 23 of this embodiment also functions according to the
TABLE 1, and can render same effect as in the aforesaid embodiments.
FIG. 14 shows an image correlation judging circuit of the brightness
signal/color signal separating filter according to the eighth embodiment
of this invention.
This embodiment features to dividedly compose the horizontal color signal
non-correlative energy extracting circuit 1827 and the vertical color
signal non-correlative energy extracting circuit 1829 in the sixth
embodiment shown in FIG. 12, each into two sub-circuits having mutually
different characteristics, similar to the seventh embodiment shown in FIG.
13.
Also in this embodiment, the switching circuit 23 function according to the
TABLE 1, rendering same effect as in the aforesaid embodiments.
FIG. 18 shows an image correlation judging circuit 1 according to the ninth
embodiment of this invention.
Likewise to the third embodiment shown in FIG. 9, this embodiment uses
adders 1975, 1976 and multipliers 1977, 1978, and likewise to the seventh
embodiment shown in FIG. 13, this embodiment includes a horizontal color
signal non-correlative energy extracting circuit 1927 and a vertical color
signal non-correlative energy extracting circuit 1929.
Namely, this embodiment has two horizontal color signal non-correlative
energy extracting circuits 1927a, 1927b, and the former outputs DCH1 based
on three types of signals 101, 102, and 103, and the latter outputs DCH2
based on a signal 102.
These outputs DCH1 and DCH2 are supplied to the adder 1975a along with the
output DYH from the horizontal brightness signal non-correlative energy
extracting circuit 1928.
The adder 1975a adds the output DCH1 of the horizontal color signal
non-correlative energy extracting circuit 1927a with the output DYH of the
horizontal brightness signal non-correlative energy extracting circuit
1928, and outputs the added result as horizontal non-correlative energy
DH11 to the comparing circuit 1945.
The adder 1975b adds the output DCH2 of the horizontal color signal
non-correlative energy extracting circuit 1927b with the output DYH of the
horizontal brightness signal non-correlative energy extracting circuit
1928, and outputs the added result as horizontal non-correlative energy
DH12. This energy is then multiplied by a constant m, and the multiplied
result is supplied to the comparing circuit 1946.
On the other hand, this embodiment includes two vertical color signal
non-correlative energy extracting circuits 1929a, 1929b, and the former
outputs DCV 1 based on three kinds of signals 101, 102, and 103, while the
latter outputs DCV2 based on signals 101 and 102.
These outputs DCV1 and DCV2 enter the adders 1976a and 1976b, respectively,
along with the output DYV of the vertical brightness signal
non-correlative energy 1930.
The adder 1976a adds the output DCV1 of the vertical color signal
non-correlative energy extracting circuit 1929a with the output DYV of the
vertical brightness signal non-correlative correlative energy extracting
circuit 1930, and outputs the added result as vertical non-correlative
energy DV11 to the comparaing circuit 1946.
The adder 1976b adds the output DCV2 of the vertical color signal
non-correlative energy extracting circuit 1929b with the output DYV of the
vertical brightnes signal non-correlative energy extracting circuit 1930,
and outputs the added result as vertical non-correlative energy DV12. This
energy DV12 is then multiplied by a constant n in the multiplier 1978 and
thereafter is outputted to the comparing circuit 1945.
The comparing circuits 1945 and 1946, as the other embodiments mentioned
earlier, make judgement on the basis of the DH11, m * DH12, DV1 and n *
DV12.
Namely, the comparing circuit 1945, judges that there is vertical
correlation without horizontal correlation and outputs high level signal
115 to the judging circuit 1947 if DH11.gtoreq.n * DV12. On the contrary,
it judges that there is no vertical correlation and outputs low level
signal 115 to the judging circuit 1947 if DH11<n * DV12.
Likewise, the comparing circuit 1946 judges that there is horizontal
correlation without vertical correlation and outputs high level signal 114
to the judging circuit 1947 if DV11.gtoreq.m * DH12. On the contrary, it
judges that there is no horizontal correlation and outputs low level
signal to the judging circuit 1947 if DV11<m * DH12.
Therefore, also in this embodiment, the switching circuit operates
according to the TABLE 1, rendering the same effect as in the aforesaid
embodiments.
FIG. 19 shows an image correlation judging circuit 1 acoording to a tenth
embodiment of this invention.
This embodiment has such a composition that the adders 1975a and 1976b are
replaced by the same 2075 and 2076 respectively, and likewise the adders
1975b and 1976b are replaced by the maximum value circuit 2040 and 2041,
respectively. Further, multipliers 2037, 2038 and 2035, 2036 are provided
before the maximum value circuits 2040 and 2041, respectively.
Accordingly, in this embodiment too, the comparing circuits 2045, 2046
operates along the same logic as the ninth embodiment, and the switching
circuit functions according to the TABLE 1.
Namely, the output DCH1 of the horizontal color signal non-corrrelative
energy extracting circuit 2027a enters the adder 2075 along with the
output DYH of the horizontal brightness signal non-correlative energy
extracting circuit 2028. The adder 2075 adds the output DCH1 of the
horizontal color signal non-correlative energy extracting circuit 2027a
with the output DYH of the horizontal brightness signal non-correlative
energy extracting circuit 2028, and outputs the added result as horizontal
non-correlative energy DH1 to the comparing circuit 2045.
Meanwhile, the output DCH2 of the horizontal color signal non-correlative
energy extracting circuit 2027b is multiplied by a constant b in the
multiplier 2037 and thereafter is supplied to the maximum value circuits
2040. The value, obtained by multiplying the output DYH of the horizontal
brightness signal non-correlative energy extracting circuit 2028 by a
constant a in the multiplier 2038, is also supplied to the maximum value
circuit 2040.
The maximum value circuit 2040 compares the b * DCH with a * DYH, and
selects and outputs the larger one as horizontal non-correlative energy
DH2 to the comparing circuit 2046 through the multiplier 2043. The
multiplier 2043 multiplies the horizontal non-correlative energy DH2 by a
constant m.
The output DCV2 of the vertical color signal non-correlative energy
extracting circuit 2029b and the output DYV of the vertical brightness
signal non-correlative energy extracting circuit 2030 are supplied to the
maximum circuit 2041 via the multiplier 2035 and 2036 respectively. The
multipliers 2035 and 2036 multiply the DCV2 and the DYV by constants d and
c, respectively. The maximum value circuit 2041 compares both of these,
and outputs the obtained maximum value max (d * DCV2, c * DYV) as vertical
non-correlative energy DV2. This is then multiplied by a constant n in the
multiplier 2044 and is supplied to the comparing circuit 2045.
The comparing circuit 2046, if m * DH2>DV1, outputs a high level signal 114
to the judging circuit 2047 regarding that there is vertical correlation
without horizontal correlation. On the contrary, if m * DH2.ltoreq.DV1, it
outputs a low level signal 114 to the judging circuit 2047 regarding that
there is no vertical correlation.
The comparing circuit 2045, if n * DV2>DH1, outputs high level signal 115
regarding that there is horizontal correlation without vertical
correlation. On the contrary, if n * DV2.ltoreq.DH1, it outputs low level
signal to the judging circuit 2047 regarding that there is no horizontal
correlation.
Therefore, also in this embodiment, the switching circuit operates
according to the TABLE 1, rendering the same effects as embodiments
earlier mentioned.
Although in the embodiments described above, the composite color television
signal has been sampled at quadruple the frequency of the color subcarrier
concorded with the horizontal scan frequency, any other frequency than
such quadruple frequency can be used for sampling, on the condition that
the sampling points are arranged in grids on the screen.
It should be noted that the digital filter used in the embodiments is
nothing more than exemplary, and other means e.g. one composed of multiple
filters, can also be used.
Further, despite that the embodiments described on NTSC type brightness
signal/color signal separating filter, it is also possible, as shown in
FIG. 15, to apply the composition to PAL type filter using a two
line-delay of the composite color television signal by a third delay
circuit 79 and a fourth delay circuit 80, instead of the one line-delay by
the first delay circuit 13 and the second delay circuit 14 in FIG. 1, with
other components being the same as FIG. 1. The same effect can be obtained
by this design, too.
Still further, the FIR filter, which constituted the digital filters in the
embodiments, can be substituted by the IIR filter.
As described above, according to this invention, since the brightness
signal/color signal separating filter is properly used depending on the
vertical and horizontal image correlations of composite color television
signal, the undesirable influence caused by mutual leakage of brightness
signal and color signal to the another's channel can be reduced, thereby
minimizing the dot jamming.
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