JP2595746B2 - Scan line interpolation circuit - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scanning line interpolation circuit for converting an interlaced signal into a non-interlaced signal on the receiver side.

[Prior Art] FIG. 3 is a block diagram showing a configuration of a scanning line interpolation circuit according to the prior art of the present inventors.

In the figure, reference numeral (1b) denotes an input terminal to which a transmitted interlace signal is input. The input interlace signal (201) is provided as a first input of an adder (8a), and is also input to a 1H delay circuit (3b) and a 263H delay circuit (3c). The output (202) of the 1H delay circuit (3b) is provided as a second input of the adder (8a). The output (203) of the adder (8a) is provided as a first input of the adder (8c) via a multiplier (9a),
Provided as the first input of the MIX circuit (6). On the other hand, M
The output (205) of the 263H delay circuit (3c) is given as the second input of the IX circuit, and the motion information (7) is input as the third input.
Is output (209). An output (206) of the LD demodulation circuit (5) is provided as a second input of the adder (8c),
The output (207) of the adder (8c) is provided as a first input of the adder (8d) via the LPF (4a). MIX circuit (6)
Of the adder (8d) via the HPF (4b)
Is given as input. Output of adder (8d) (212)
Is output to the output terminal (2b).

Next, the operation will be described. The operation of FIG. 3 will be described with reference to FIG.

Input interlace signal (201) and 1H delay circuit (3b)
Are added by an adder (8a) and then multiplied by a factor of 1/2 by a multiplier (9a). The output (204) is (B + D) / 2 in the calculation for the scanning lines B and D in FIG.
Is equivalent to Next, a line difference signal (hereinafter, referred to as an LD signal) as an auxiliary signal for scanning line interpolation by an adder (8c), that is, a difference signal LD = C between the average of upper and lower scanning lines of the target scanning line and the target scanning line. The sum with the output signal (204) is obtained using-(B + D) / 2. However, since the LD signal (206) includes only horizontal low-frequency component, which upon the LD _L, L
D _L = C _L − (B _L + D _L ) / 2 (where C _L , B _L , and D _L are C,
B, D horizontal low frequency components. ), And the adder (output 8c) (207) is, (B + D) / 2 + LD L = {(B L + B H) + (D L + D H)} / 2 + C L - (B L + D L) / 2 = _{C L + (B H + D} H) / 2 ( where, B _H, D _H of B, the horizontal high-frequency component of the D, C _L is the horizontal low-frequency component of C.) expressed and, LPF the (4a) the first input of the via adders (8d) (208), expressed as X _L since hits the horizontal low-frequency component, X _L = C _L can be obtained.

Next, the output (205) of the 263H delay circuit (3c) corresponds to the scanning line A in FIG. 4B, and is output to the MIX circuit (6) together with the output (B + D) / 2 of the multiplier (9a). Is entered. MIX
In the circuit (6), according to the motion information (209), A which is the information of one field before and the average of the upper and lower scanning lines (B + D).
/ 2 is determined, and a motion coefficient α is applied to output (210). This output signal (210) can be written as α · (B + D) / 2 + (1−α) · A. The output of the MIX circuit (6) (210) is input to HPF (4b), when expressed as X _H because the output (211) corresponds to horizontal high-frequency component of the interpolated scanning line signal, X _H = α · (B _H + D _H ) / 2 + (1−α) · A _H (where A _H , B _H , and D _H are horizontal high-frequency components of A, B, and D, and α is a motion adaptation coefficient.) Adder (8d) in), and horizontal low frequency component X _L of the interpolated scanning line signal and horizontal high frequency component X _H is added together, interpolation scanning line X = X _L + X _H as having a horizontal entire band.

[Problems to be Solved by the Invention] Since the conventional scanning line interpolation circuit is configured as described above, the information of the field of the scanning line to be interpolated according to the motion information and the information of the previous field are mixed. As a result, the time point of the interpolation data may be different depending on the degree of movement, resulting in a problem that the movement becomes unnatural. The present invention has been made in order to solve the above-described problems, and regardless of the degree of motion of an image, the interpolated information always retains the information at the time of the field to be interpolated, whereby a stable motion can be obtained. It is an object of the present invention to obtain a reproducible scanning line supplement circuit.

[Means for Solving the Problems] A scanning line interpolation circuit according to the present invention is a scanning line interpolation circuit for converting an interlace signal into a non-interlace signal. If the band is μ0,
For the horizontal low frequency components of the scanning line X to be interpolated, the horizontal frequency band of which is μ0 or less, the LD signal (line difference signal) for the scanning line X and the scanning positioned above and below the scanning line X The horizontal frequency band of the horizontal frequency band of the weighted average of the line is determined as the sum of the horizontal low frequency components of μ0 or less, and at least the horizontal high frequency component of the scanning line X whose horizontal frequency band of μ0 or more is interpolated. The horizontal frequency band of a signal obtained by multiplying a scan line located above and below a scan line X to be interpolated and a scan line in a field before and after the scan line X to be interpolated by a coefficient according to motion information and adding the same is obtained. It is determined as a horizontal high frequency component of μ0 or more.

[Operation] The MIX circuit according to the present invention, when interpolating a scanning line, uses the average of the upper and lower sides of the scanning line and the average of the scanning lines of the fields before and after the scanning line based on the motion information to perform the scanning to be interpolated. Make the line data appropriate for the field.

[Example] Hereinafter, the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of a scanning line interpolation circuit according to one embodiment of the present invention. In the figure, components denoted by the same reference numerals as those of the conventional example shown in FIG. 3 represent the same components and operations as those of the conventional example.

In the figure, (1a) is an input terminal to which a transmitted interlace signal is input. The input interlace signal (101) is input to the 262H delay circuit (3a) and is also provided as a first input of the adder (8b). The output (102) of the 262H delay circuit (3a) is the 1H delay circuit (3
It is input to b) and also to the 263H delay circuit (3c), and is also provided as a first input of the adder (8a). The output (103) of the 1H delay circuit (3b) is
a) is given as the second input. 263H delay circuit (3
The output (104) of c) is provided as a second input of the adder (8b). The output (105) of the adder (8a) is a multiplier (9a)
, And as the first input of the adder (8c) and the MIX circuit (6). The output (106) of the adder (8b) becomes the output (108) via the multiplier (9b) and is given as the second input of the MIX circuit (6). An output (110) of the motion information circuit (7) is provided as a third input of the MIX circuit (6). The output (109) of the LD demodulation circuit (5) is provided as a second input of the adder (8c), and the output (111) of the adder (8c) is supplied to the adder (8d) via the LPF (4a). Provided as a first input. On the other hand, the output (112) of the MIX circuit (6) is provided as a second input of the adder (8d) via the HPF (4b). The output (115) of the adder (8d) is output to the output terminal (2a).

Next, the operation will be described. The operation of FIG. 1 will be described with reference to FIG.

When the scanning line signal E in FIG. 2B is input from the input terminal (1a), the output (102) of the 262H delay circuit (3a) becomes the scanning line D, and the output (103) of the 1H delay circuit (3b). ) Is the scanning line B. The output (102) of the 262H delay circuit (3a) and the output (103) of the 1H delay circuit (3b) are added by the adder (8a) and then multiplied by 1/2 by the multiplier (9a). The output (107) becomes (B + D) / 2, and the adder (8c)
As one input.

On the other hand, the LD demodulation circuit (5) demodulates the transmitted LD transmission signal and outputs an LD signal (109). The LD signal for the scanning line X to be interpolated includes the original signal C of the scanning line X to be interpolated and the scanning lines B and D above and below it.
Is the difference signal LD = C− (B + D) / 2 from the average of (B + D) / 2. However, as described above, generally LD signal on account of the transmission path, for example because 1.5MHz only horizontal low-frequency components below only come transmitted, which is expressed as _{LD L, LD L = C L} - ( B _L + D _L ) / 2 (where C _L , B _L , and D _L represent horizontal low-frequency components of 1.5 MHz or less of C, B, and D, respectively), and the adder (8
c) is given as the other input.

Accordingly, the output of the adder (8c) (111) is, (B + D / 2 + LD L = ((B L + B H) + (D L + D H)) / 2 + C L + (B L + B L) / 2 = ( _BH + _DH ) / 2 + _CL (where _BH and _DH represent horizontal high frequency components of B and D, for example, 1.5 MHz or more.) The signal (111) is an LD.
The transmission band cut-off frequency of the signal (in this case 1.5MHz) is input to the LPF (4a) to only C _L is a horizontal low-frequency components below 1.5MHz is, as the output of LPF (4a) (113) Is output. The signal (113) Thus, (hereinafter 1.5 MHz) horizontal low-frequency component of the interpolated scanning line X for X _L, is equal signal to the original signal at all, i.e. X _L = C _L playback. The operation so far is exactly the same as the conventional example shown in FIG.

On the other hand, D of the output (102) of the 262H delay circuit (3a) is 263
Since it is also input to the H delay circuit (3c), the 263H delay circuit (3c
From c), A is output as its output (104). In the adder (8b), E as the signal (101) and A as the signal (104) are added, and the coefficient (1 / b) is added in the multiplier (9b).
2 is multiplied, and as the output (108) of the multiplier (9b), (A +
E) / 2 is output.

In the MIX circuit (6), (B + D) / 2 which is the output (107) of the multiplier (9a) is used as a first input and the multiplier (9b)
The output (108) of (A + E) / 2 is given as the second input. These are equal to the average of the scanning lines above and below the scanning line X to be interpolated, and the average of the scanning lines in the fields before and after the scanning line X to be interpolated. on the other hand,
The motion information circuit (7) determines how much the interpolation scanning line X is a moving image, and outputs a motion adaptive coefficient α to its output (11
Output as 0). That is, when scanning line X is determined to be a complete still image, α = 0 is output. When scanning line X is determined to be a complete moving image, α = 1 is output.
An intermediate value α of <1 is output. In the MIX circuit (6),
The first input (B + D) / 2 and the second input (A + E) are obtained by using the motion adaptation coefficient α input from the motion information circuit (7).
.Alpha..multidot. (B + D) / 2 + (1-.alpha.). Multidot. (A + E) / 2, and outputs it as an output signal (112).

Therefore, the output signal (112) is (B +
D) / 2, that is, the average of the upper and lower scanning lines, and at the time of a complete still image, (A + E) / 2, that is, the average of the scanning lines of the preceding and succeeding fields. In the case of a complete still image, information does not change in the time direction.
+ E) / 2 and the original signal C are completely equal.

The output (112) of the MIX circuit (6) uses the horizontal transmission band of the LD signal as a cutoff frequency (in this case, 1.5 MHz) HPF (4b)
And outputs only the horizontal high frequency component of 1.5 MHz or more. Therefore, its output (114) can be written as α · (B _H + D _H ) + (1−α) · (A _H + E _H ) / 2. (However, B _H , D _H , A _H , and E _H represent the horizontal high frequency components of B, D, A, and E.) Thus, the signal (114) has a frequency of 1.5 MHz or more of the interpolation scanning line X. X _H = α · (B _H + D _H ) + (1−α) · (A _H + E _H ) / 2 is created as the horizontal high frequency component X _H. The resulting interpolated signal X _H at the time of fully static image _{here, X H = (A H +} E H) / 2 and since, fully equal to the horizontal high frequency components C _H above 1.5MHz of the original signal C become. The adder (8d), the 1.5MHz The following addition and a horizontal low-frequency component X _L and the 1.5MHz or more horizontal high frequency components X _H, interpolated scan lines as having a full horizontal band X = X _L + _XH is obtained. The interpolation signal X thus obtained is equal to the original signal over the entire horizontal band in the case of a complete still image, and the horizontal low frequency component of 1.5 MHz or less in the case of a complete moving image. And the horizontal high frequency component of 1.5 MHz or more becomes the horizontal high frequency component of the average value of the upper and lower scanning lines. Also, in cases other than complete moving images or complete still images, horizontal low-frequency components below 1.5 Mz are completely equal to the original signal and become 1.5 MHz.
As for the above horizontal high frequency components, the average value of the upper and lower scanning lines and the horizontal high frequency component of the average value of the scanning lines of the preceding and succeeding fields are used. Note that, in the above embodiment, the case where the horizontal band of the transmitted LD signal is 1.5 MHz has been described, but another band may be used.

[Effects of the Invention] As described above, according to the present invention, the data of the scanning line to be interpolated by the MIX circuit is obtained by averaging the scanning lines above and below the scanning line, and averaging the scanning lines in the fields before and after the scanning line. Therefore, data suitable for the field of the scanning line to be interpolated can be obtained, and there is an effect that a natural and stable moving image can be reproduced.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of a scanning line interpolation circuit according to an embodiment of the present invention, FIG. 2 is a diagram showing a scanning line structure for explaining this embodiment, and FIG. FIG. 4 is a block diagram showing the configuration, and FIG. 4 is a scanning line structure diagram for explaining a conventional scanning line interpolation circuit. In the figure, 1a and 1b are input terminals, 2a and 2b are output terminals, 3a to
3c is delay circuit, 4a is LPF, 4b is HPF, 5 is LD demodulation circuit, 6
Is a MIX circuit, 7 is a motion information circuit, 8a to 8d are adders, 9a to 9
b is a multiplier. In the drawings, the same reference numerals indicate the same or corresponding parts.

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Reiko Suehiro, 1 Baba Zujo, Nagaokakyo-shi, Kyoto, Japan Inside the Electronic Product Development Laboratory, Mitsubishi Electric Corporation (56) References JP-A-3-226084 (JP, A)

Claims (1)

(57) [Claims] In a scanning line interpolation circuit for converting an interlaced signal into a non-interlaced signal, if a horizontal frequency band of a transmitted LD signal (line difference signal) is μ0, scanning to be interpolated is performed. For the horizontal low-frequency component whose horizontal frequency band of the line X is μ0 or less, the weighted average of the LD signal (line difference signal) for the scanning line X and the scanning lines positioned above and below the scanning line X is calculated. The horizontal frequency band is obtained as the sum of horizontal low frequency components of μ0 or less. The horizontal high frequency component of the scanning line X whose interpolation is to be μ0 or more is at least the scanning line X to be interpolated. With respect to the scanning lines positioned above and below, and the scanning lines in the fields before and after the scanning line X to be interpolated,
A scanning line interpolation circuit characterized in that a horizontal frequency band of a signal obtained by multiplying by a coefficient according to motion information and adding up is obtained as a horizontal high frequency component of μ0 or more.