Video pattern noise processor

Low-frequency noise in the video output of a charge-injection-device imager is cancelled by delaying the low-frequency components of video plus noise for one horizontal interval and subtracting therefrom the undelayed noise from corresponding cells of the same row of the imaging matrix. High frequency noise is eliminated in a separate channel by low-level clipping of the high-frequency component of the video signal. The high-frequency video component is delayed for one horizontal interval to align it with the low-frequency video component and the two components are summed to reconstruct the full video signal from which both high-frequency and low frequency noise is absent.

BACKGROUND OF THE INVENTION 
The present invention relates to electro-optical imaging systems and, more 
particularly, to video processing apparatus for solid state imaging 
systems. 
Electro-optical imaging sensors are roughly divided into camera-tubes 
contained within evacuated envelopes and solid state imaging sensors in 
which a charge pattern is created by the impingement of light on a solid 
state matrix array. One type of solid state imaging sensor, which forms 
the environment with which the present invention is employed, is commonly 
known as a charge-injection device (CID). The principles underlying 
charge-injection device imagers are detailed in U.S. Pat. Nos. 3,805,062; 
3,949,162; 4,000,418; 4,011,441 and 4,011,442, the disclosures of which 
are herein incorporated by reference. 
In brief, a charge-injection device employs a silicon substrate having 
orthogonal row and column conductors thereon which are insulated both from 
the substrate and from each other. Each intersection of a row conductor 
with a column conductor provides two storage locations, one under the row 
conductor and the other under the column conductor, within which charges 
liberated from the silicon substrate by incident radiation may be stored 
by the application of appropriate voltages. The stored charges, when 
appropriately read out, form the video signal. 
Using an appropriately doped silicon substrate such as, for example, an 
n-type semiconductor, a negative voltage applied to a row or column 
conductor is effective to produce a depletion region forming a potential 
well thereunder. The potential well functions as a capacitor to collect 
the charges liberated by incident radiation. Although mutually insulated, 
the potential wells under the row and column conductors at an intersection 
thereof are so closely coupled that charges may be transferred back and 
forth therebetween without loss of stored charge. Whichever one of the row 
and column conductors is maintained at the more negative potential 
captures all of the charge from the one maintained at a less negative 
potential. In order to transfer the charge from beneath one conductor to 
beneath the other conductor, the voltage on the conductor originally 
having the larger negative voltage is reduced to a value less than the 
negative voltage on the originally less negative conductor. Equivalently, 
the negative voltage on the previously less negative conductor may be 
increased until it exceeds the negative voltage on the first-mentioned 
conductor. 
In one technique described in the referenced patents, at all times except 
during the reading-out process, the row conductors are maintained more 
negative than the column conductors. The liberated charges are therefore 
totally contained under the row conductors. In preparation for reading out 
a row, the row voltage is raised until it attains a less-negative voltage 
intermediate the column voltage and ground. This transfers all of the 
accumulated charges simultaneously in the selected row from beneath all of 
the row conductors to beneath their respective column conductors. The 
negative voltages on the column conductors are then increased one at a 
time in sequence to a less negative voltage than the selected row 
conductor. The less negative voltage may conveniently be zero volts. As 
the voltage on each column conductor is increased to zero, the charge 
stored thereunder flows back beneath its associated row conductor within 
the row being read out. The flow of charges in the row conductor 
occasioned by the transfer of charge from each column conductor is sensed 
to produce the output video signal. It should be noted that, since the 
only column conductors which contain charges are those in the selected 
row, the voltage sequence on the column conductors is ignored by all 
storage locations except those in the selected row. 
The readout sequence described above is non-destructive; that is, at the 
end of reading the stored charges in a row, the charges, although they 
have been transferred first from beneath the row conductors to beneath the 
column conductors and then have been sequentially transferred back again, 
remain in their original locations, undiminished. If the original voltages 
are restored on the row and column conductors, continued integration of 
incoming radiation without erasure of the previously stored charges may be 
performed. This is especially useful in low-light-level applications. In 
normal imaging applications, it is useful to erase the stored charges in a 
row just after it is read out so that a new charge pattern may be 
integrated until the next time the row is scheduled for readout. The 
charges in a row are readily cancelled or erased by raising the selected 
row voltage to zero while the column voltages are also at zero. This 
injects sufficient charges into the storage locations to cancel any charge 
pattern which they may have acquired, and hence the name "charge-injection 
device". 
Noise is a problem in all imaging devices. The type of noise and its 
severity varies with the type of imaging device and with its required 
peripheral equipment. I have discovered that charge-injection imaging 
devices suffer from two sources of noise giving rise to pattern noise; 
namely, switching noise and capacitance variation noise. 
The magnitude of the video output signal of a charge-injection device is 
usually a small fraction of the magnitude of the column-select signal 
voltage which is applied to the column conductors. The mutually insulated 
row and column conductors function as small capacitors which couple a 
portion of the column-select voltage for superposition onto the video 
signal on the selected row conductor on which the video signal is 
transmitted to external circuits. For common television signal rates, the 
column-select signal has frequency components in the range of 3.5 MHz, 7 
MHz and higher. The 3.5 MHz components, in particular, produce a pattern 
noise in the video signal which is objectionable when large values of 
video gain are employed. Simple filtering of the video to remove the 3.5 
MHz component is not desirable since such filtering would also remove 
significant video information existing in the vicinity of this frequency. 
Capacitance variation noise is produced by slight differences in the values 
of capacitances of the cells making up the matrix. As a consequence, 
uniform illumination of all of the cells induces the storage of slightly 
different amounts of charge. In effect, the differences in cell 
capacitance produces a video signal variation from cell to cell even when 
all of the cells are uniformly illuminated. When a non-uniform scene is 
imaged on the matrix, the pattern noise produced by the capacitance 
differences is essentially superimposed on the video representing the 
scene. This effect is particularly troublesome when high video gain is 
used in low-light-level applications. 
The prior art has taken advantage of the fact that the capacitance pattern 
of corresponding cells in adjacent rows is similar. Two adjacent rows are 
simultaneously enabled and read out by the same sequence of voltages on 
the row and column conductors. The pattern noise from the immediately 
preceding row, which was erased at the end of its readout, is inverted and 
subtracted, cell-by-cell, from the output of the row containing the 
desired video information. Due to the similar capacitances of 
corresponding cells in adjacent rows, the inverted pattern noise from an 
erased row, subtracted from the video plus pattern noise from 
corresponding storage locations in the immediately following row, cancels 
a substantial portion of the pattern noise originating in charge 
variation. This technique has permitted the successful use of 
charge-injection imaging devices in applications where their small size 
and ruggedness are an advantage. 
Even after cancelling pattern noise using adjacent-row noise residue, a 
small residue of pattern noise remains due to the fact that, although 
adjacent-row storage locations are very similar, they are not, in fact, 
exactly the same. Thus, in demanding imaging applications including, for 
example, low-light-level imaging in which high video gain is required, a 
reduced but still-visible pattern noise is present. 
U.S. Pat. No. 4,079,423 discloses a technique in which the output from the 
same row before and after video erasure is used for pattern-noise 
cancellation. The video data of a row, accompanied by its pattern noise, 
is delayed for one horizontal interval (1H) and is then added to the 
inverted undelayed pattern noise from the same line from which the video 
information has been erased. Since the sources of both of these signals 
are identical, improved cancellation is achieved. Any residue of pattern 
noise which remains after cancellation is inverted in succeeding lines to 
provide visual cancellation of pattern noise. 
OBJECTS AND SUMMARY OF THE INVENTION 
Accordingly, it is an object of the invention to provide a pattern noise 
processor which overcomes the drawbacks of the prior art. 
It is a further object of the invention to provide a pattern noise 
processor which separates low-frequency and high-frequency components of 
pattern noise in a video signal and separately processes the low- and 
high-frequency components for cancellation of both capacitance variation 
noise and switching noise. 
It is a further object of the invention to provide a pattern noise 
processor in which low-frequency video with pattern noise is delayed in 
one channel for cancellation by undelayed noise, and high frequency video 
is separately noise processed and delayed in a second channel. The delayed 
processed low-frequency and high-frequency components of the video signal, 
now minus noise, are combined to produce a clean video output signal. 
It is a further object of the invention to provide a pattern noise 
processor using a single delay element to delay noise-processed, 
high-frequency video and unprocessed low-frequency video plus pattern 
noise. An undelayed low-frequency noise is subtracted from the combined 
delayed signal to cancel low-frequency noise. 
Briefly stated, the present invention provides a pattern noise processor in 
which low-frequency noise in the video output of a charge-injection-device 
imager is cancelled by delaying the low-frequency components of video plus 
noise for one horizontal interval and subtracting therefrom the undelayed 
noise from corresponding cells of the same row of the imaging matrix. High 
frequency noise is eliminated in a separate channel by low-level clipping 
of the high-frequency component of the video signal. The high-frequency 
video component is delayed for one horizontal interval to align it with 
the low-frequency video component and the two components are summed to 
reconstruct the full video signal from which both high-frequency and 
low-frequency noise is absent. 
According to an embodiment of the invention there is provided a pattern 
noise processor for cancelling pattern noise in a video signal from a 
charge-injection device, the charge-injection device being of a type which 
simultaneously reads out first and second signals, the first and second 
signals respectively containing contents of corresponding charge storage 
locations in first and second rows of the charge-injection device, the 
charge storage locations in the first row containing the video signal and 
pattern noise and the charge storage locations in the second row 
containing only pattern noise, having had any video therein erased 
comprising means for delaying one of the first and second signals for a 
predetermined time, the predetermined time being sufficient to coincide 
portions of the one of the first and second signals with portions of the 
other of the first and second signals originating in the same storage 
locations of the same row, means for differencing the delayed and 
undelayed signals to produce a noise-reduced signal, means for removing a 
high-frequency component of the noise-reduced signal above a predetermined 
frequency to produce a noise-reduced, low-frequency component, means for 
passing a high-frequency component of at least the first signal, the 
high-frequency component including all frequencies above the predetermined 
frequency, means for clipping portions of the high-frequency component 
having positive and negative amplitudes less than a predetermined value to 
produce a clipped high-frequency component, means for delaying the 
high-frequency component for the predetermined time to produce a clipped 
delayed high-frequency component and means for adding the clipped 
high-frequency component and the noise-reduced, low-frequency component. 
According to a feature of the invention there is provided a pattern noise 
processor for cancelling pattern noise in a video signal from a 
charge-injection device, the charge-injection device being of a type which 
simultaneously reads out first and second signals, the first and second 
signals respectively containing contents of corresponding charge storage 
locations in first and second rows of the charge-injection device, the 
charge storage locations in the first row containing the video signal and 
pattern noise and the charge storage locations in the second row 
containing only pattern noise, having had any video therein erased 
comprising first low-pass means for passing a first frequency range of the 
first signal, the first frequency range including substantially all 
frequencies below a predetermined frequency, and for blocking 
substantially all frequencies above the predetermined frequency to produce 
a first low-frequency component, second low-pass means for passing the 
first frequency range of the second signal to produce a second 
low-frequency component, means for delaying one of the first and second 
low-frequency components for a predetermined time, the predetermined time 
being sufficient to coincide portions of the one of the first and second 
low-frequency components with portions of the other of the first and 
second low-frequency components originating in the same storage locations 
of the same row, means for subtracting the delayed and undelayed 
low-frequency components to produce a substantially pure low-frequency 
video component from which low-frequency components of the pattern noise 
are cancelled, high-pass means for passing all frequencies in at least the 
first signal higher than the predetermined frequency to produce a 
high-frequency component, means for clipping all portions of the 
high-frequency component having an amplitude lower than a predetermined 
positive and negative amplitude to produce a clipped high-frequency 
component, means for delaying the clipped high-frequency component for the 
predetermined time and means for adding the delayed clipped high-frequency 
component to the substantially pure low-frequency video component to 
produce a full-frequency video signal from which both low-frequency and 
high-frequency pattern noise are substantially eliminated. 
According to a further feature of the invention there is provided a method 
for cancelling pattern noise in a video signal from a charge-injection 
device, the charge-injection device being of a type which simultaneously 
reads out first and second signals, the first and second signals 
respectively containing contents of corresponding charge storage locations 
in first and second rows of the charge-injection device, the charge 
storage locations in the first row containing the video signal and pattern 
noise and the charge storage locations in the second row containing only 
pattern noise, having had any video therein erased comprising delaying one 
of the first and second signals for a predetermined time, the 
predetermined time being sufficient to coincide portions of the one of the 
first and second signals with portions of the other of the first and 
second signals originating in the same storage locations of the same row, 
differencing the delayed and undelayed signals to produce a noise-reduced 
signal, removing a high-frequency component of the noise-reduced signal 
above a predetermined frequency to produce a noise-reduced, low-frequency 
component, passing a high-frequency component of at least the first 
signal, the high-frequency component including all frequencies above the 
predetermined frequency, clipping portions of the high-frequency component 
having positive and negative amplitudes less than a predetermined value to 
produce a clipped high-frequency component, delaying the high-frequency 
component for the predetermined time to produce a clipped delayed 
high-frequency component and adding the clipped high-frequency component 
and the noise-reduced, low-frequency component. 
The above, and other objects, features and advantages of the present 
invention will become apparent from the following description read in 
conjunction with the accompanying drawings, in which like reference 
numerals designate the same elements.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring to FIG. 1, there is shown, generally at 10, a solid state imaging 
system according to an embodiment of the invention. A lens 12 images a 
pattern of light intensities from a scene 14 onto a matrix array of a 
charge-injection device 16. Two video signals, E1 and E2, are read out 
from charge-injection device 16 by a readout circuit 8. Video signals E1 
and E2 are applied on lines 20 and 22 to respective inputs of 
preamplifiers 24 and 26 in a preamplifier subsystem 27. Video signal E1, 
applied to preamplifier 24, contains only pattern noise PN from the sensor 
row which was read out and then erased in the immediately preceding 
horizontal interval. Video signal E2, applied to preamplifier 26, contains 
video plus unwanted pattern noise S+PN from the row immediately following 
the one providing signal E1. 
A pattern noise processor 28, to be more fully detailed hereinafter, 
receives the amplified versions of video signals E1 and E2 and provides 
noise cancellation of both capacitance variation noise and switching noise 
from the video signal in order to provide substantially noise-free video 
to following circuits such as, for example, a video monitor 30 or a video 
processor 32. Video processor 32 may be, for example, a portion of a 
robotics system (the remainder of which is not shown) for performing 
pattern recognition, or other activity, on the video signal. The processed 
video from video processor 32 is applied on a line 34 to external circuits 
which are not of concern to the present invention. 
In some embodiments of charge-injection device 16 and readout circuit 18, 
it is convenient to alternate the signals on lines 20 and 22 whereby, in 
one horizontal interval, line 20 contains the new video data and line 22 
contains pattern noise and, in the next horizontal interval, line 22 
contains the new video data and line 20 contains pattern noise. One 
skilled in the art would recognize that a conventional multiplexer (not 
shown) may be used following preamplifier subsystem 27 to alternately 
reverse the lines on which such signals are fed from readout circuit 18 to 
succeeding circuits and, in fact, such an embodiment is preferred. 
Referring now to FIG. 2, there is shown a more detailed block diagram of 
the embodiment of the invention of FIG. 1. Charge-injection device 16 
consists of a plurality of parallel row conductors 36 on a substrate 37, 
each connected to a row control circuit 38, and a plurality of parallel 
column conductors 40 on substrate 37, each connected to a column control 
circuit 42. Row conductors 36 and column conductors 40 cross at 
intersections 44 where they are mutually insulated from each other. A 
clock 46 provides appropriate timing signals for mutually timing the 
activities of row control circuit 38 and column control circuit 42. Each 
intersection 44 of a row conductor 36 with a column conductor 40 provides 
a sensing cell within which charges, liberated from substrate 37 by 
incident radiation, may be stored in the presence of an appropriate 
voltage as explained hereinabove. Each intersecting row conductor 36 and 
column conductor 40 provides an interline capacitance therebetween 
symbolized by a mutual capacitance 47 bridging each intersection 44. In 
addition to mutual capacitances 47, each row conductor 36 and each column 
conductor 40, in the vicinity of each intersection 44, exhibits a 
capacitance to substrate 37 which is herein understood to exist but is not 
shown in the interest of avoiding clutter in the drawing. For present 
purposes, readout circuit 18 and charge-injection device 16 are 
conventional and further details, beyond those mentioned above, are 
unnecessary for a full understanding of the invention and are therefore 
omitted herefrom but may be found in the referenced patents. 
Amplified pattern noise signal PN from preamplifier 24 is applied to a 
minus input of a subtractor 48 and to an input of a low-pass filter 50. 
Low-pass filter 50 has a cutoff frequency of about 2 MHz. The 
low-frequency component of pattern noise signal PNL from low-pass filter 
50 is applied to a minus input of a subtractor 52. The 
video-plus-pattern-noise signal S+PN from preamplifier 26 is applied to a 
plus input of subtractor 48 and to an input of low-pass filter 54. 
Low-pass filter 54 has a low-pass characteristic identical to low-pass 
filter 50; that is, low-pass filter 54 passes frequencies below about 2 
MHz and blocks higher frequencies. The low-frequency components SL+PNL 
from low-pass filter 54 are delayed one horizontal interval in a 1H delay 
56, to make them coincide with corresponding noise components from 
low-pass filter 50, before being applied to a plus input of subtractor 52. 
Since substantially all of the noise resulting from capacitance 
differences in the cells of charge-injection device 16 fall below the 
cutoff frequency of low-pass filter 50 and low-pass filter 54, and since 
both signals subtracted in subtractor 52 are derived from the same cells 
of charge-injection device 16, substantially complete and perfect 
cancellation of pattern noise due to cell capacitance differences is 
achieved in subtractor 52. Thus, the output SLD of subtractor 52 is a 
substantially perfect representation of the low-frequency components of 
the video signal from charge-injection device 16 from which all of the 
pattern noise has been cancelled. If the output SLD of subtractor 52 were 
displayed (after the addition of appropriate synchronizing signals) on 
video monitor 30 (FIG. 1), the displayed signal would be noise free, but 
would lack the fine details which are contained in the removed 
high-frequency component. 
The existence of mutual capacitances 47 between row conductors 36 and 
column conductors 40 couples switching noises generated by column control 
circuit 42 onto row conductors 36 and thus couples switching noises into 
the video connected through row control circuit 38 to pattern noise 
processor 28. I have discovered, however, that the most objectionable 
parts of such switching noises are found below about 2 MHz. In addition, 
although switching noises above 2 MHz may be inconvenient when displayed 
on a monitor with high video gain, their amplitude can be reduced to a 
small fraction of the amplitude of the video signals upon which they are 
superimposed. 
Still referring to FIG. 2, subtractor 48 subtracts the pattern noise PN of 
the preceding row from the video plus pattern noise of the current row and 
applies the result to high-pass filter 58. Due to the similarity between 
the pattern noise in corresponding cells of adjacent rows, subtractor 48 
provides a substantial reduction in the pattern noise applied to high-pass 
filter 58. High-pass filter 58 has a high-pass characteristic which is the 
complement of low-pass filters 50 and 54; that is, high-pass filter 58 
passes all frequency components above about 2 MHz and blocks those below 2 
MHz. The output SH+PNH of high-pass filter 58 represents the 
high-frequency components of video S with the noise PN substantially 
reduced by cancellation in subtractor 48. Low-amplitude portions of signal 
SH+PNH are removed in a low-level clipper 60. Since substantially all of 
the noise PNH in the high-frequency signal is of low amplitude compared to 
the amplitude of the high-frequency component of the video signal SH, a 
moderate level of clipping within low-level clipper 60 is capable of 
removing substantially all of the high-frequency noise PNH and of applying 
a substantially pure high-frequency component of the video signal SH to a 
1H delay 62. The substantially pure high-frequency component SH of the 
video signal is delayed within 1H delay 62 for one horizontal interval 
before applying a delayed high-frequency component SHD to a plus input of 
an adder 63. The output SLD of subtractor 52, which is a substantially 
pure delayed low-frequency component, is applied to a second plus input of 
adder 63. The output of SLD+SHD of adder 63 is an essentially pure replica 
of the original video signal S with both low-frequency and high-frequency 
noises cancelled. 
Referring to FIG. 3A, a single line of video read out from one row of 
charge-injection device 16 containing video plus switching pattern noise 
S+PN is shown. Low-frequency noise is omitted from FIG. 3A. The scene 
producing the video signal of FIG. 3A is one having a single bright 
central portion surrounded on each side by a dark portion giving rise to a 
single steep-sided, high-amplitude portion 64 surrounded on each side by a 
lower amplitude portion 66. Switching noises appear as ripples 68 on 
high-amplitude portion 64 and lower amplitude portions 66 having 
peak-to-peak maximum amplitudes which are very much smaller than the 
amplitudes of the excursions of the video signal between lower amplitude 
portions 66 and high-amplitude portion 64. The low-frequency component of 
the video signal SL (See FIG. 2), such as may be seen exiting low-pass 
filter 50, is shown in FIG. 3B. Due to the filtering action of low-pass 
filter 50 and low-pass filter 54, ripples 68 superimposed on the video 
signal of FIG. 3A are completely removed. Thus, ignoring low-frequency 
noise, high-amplitude portion 64' and lower amplitude portions 66' are 
smooth and ripple-free. Unfortunately, the loss of the high-frequency 
components causes the sides of the transitions between lower amplitude 
portions 66' and high-amplitude portions 64' to slope rather than to rise 
steeply as was the case with the unfiltered signal in FIG. 3A. 
Referring now to FIG. 3C, the output SH+PNH of high-pass filter 58 (FIG. 2) 
is shown containing the high-frequency video component SH with the 
high-frequency pattern noise PNH superimposed thereon. High-frequency 
video component SH includes a sharp positive-going peak 70 coinciding with 
the positive excursion of the unfiltered video signal and a sharp 
negative-going peak 72 coinciding with the negative excursion of the 
unfiltered video signal. Except for sharp positive-going peak 70 and sharp 
negative-going peak 72, the high-frequency video signal plus 
high-frequency pattern noise SH+PNH remains in the vicinity of zero, 
disturbed only by low-amplitude ripples 68. It will be recognized that 
virtually all of the information in the high-frequency signal shown in 
FIG. 3C is contained in sharp positive-going peak 70 and sharp 
negative-going peak 72. Low-level clipper 60 (FIG. 2) removes all 
low-amplitude components of the signal in between lower clipping limit 74 
and upper clipping limit 76 to totally eliminate substantially all of 
ripples 68 from its output and to produce the substantially pure 
high-frequency video component SH. 
Referring now also to FIG. 3D, when sharp positive-going peak 70 and sharp 
negative-going peak 72 of FIG. 3C are added to the filtered low-frequency 
video component of FIG. 3B, both delayed by one horizontal interval in 
their respective 1H delay lines, the original steep-sided video signal of 
FIG. 3A, without the high-frequency switching noise represented by ripples 
68, is produced. 
According to the preceding, the low-frequency pattern noise in the video 
output of charge-injection device 16 is cancelled by subtracting the 
low-frequency component of pattern noise of a row from the delayed 
low-frequency component of the video signal which is accompanied by 
low-frequency component of pattern noise of the same row. The 
high-frequency pattern noise in the high-frequency component of the video 
signal read out from a row is cancelled by clipping or eliminating 
low-amplitude components of the high-frequency component of the video 
signal. The clipped high-frequency component is delayed to align it with 
the noise-cancelled low-frequency component before adding the 
low-frequency and high-frequency components to produce the entire 
noise-cancelled video signal. 
Referring now to FIG. 4, there is shown, generally at 78, a further 
embodiment of a solid state imaging system. Except for certain differences 
in a pattern noise processor 80, solid state imaging system 78 is 
identical to solid state imaging system 10 of FIG. 2, thus, the following 
description is directed specifically to pattern noise processor 80. As in 
the prior embodiment, the pattern noise signal PN is applied to a minus 
input of subtractor 48 and to an input of low-pass filter 50. The 
video-signal plus-pattern-noise S+PN is applied to a plus input of 
subtractor 48 and to an input of low-pass filter 54. The noise-reduced 
output of subtractor 48 is applied to high-pass filter 58. Low-level 
clipper 60 removes low-amplitude components in the output of high-pass 
filter 58 and applies the resulting signal to an adder 82. The 
low-frequency components of video signal plus pattern noise SL+PNL from 
low-pass filter 54 are applied to a plus input of adder 82. The output of 
adder 82 is the noise-reduced, high-frequency component of the video 
signal SH plus the low-frequency components of the video signal and 
pattern noise SL+PNL. This combined signal from adder 82 is delayed for 
one horizontal interval in a 1H delay 84 before being applied to a plus 
input of a subtractor 86. The undelayed low-frequency pattern noise signal 
PNL from low-pass filter 50 is applied to a minus input of subtractor 86. 
The subtraction of the undelayed low-frequency pattern noise PNL from the 
combined signal SL+PNL+SH eliminates the corresponding component from the 
combined signal to produce a final noise-cancelled, delayed signal 
SLD+SHD. 
A comparison of the embodiments of FIGS. 2 and 4 indicates that the 
embodiment of FIG. 4 accomplishes the same result as that of FIG. 2 while 
using only a single 1H delay instead of two 1H delays. This is 
accomplished by adding the clipped high-frequency video component to the 
noise-containing low-frequency component and delaying both components in a 
single delay line. 
Referring again momentarily to FIG. 2, it is not necessary to locate 
low-pass filters 50 and 54 upstream of 1H delay 56 and subtractor 52. 
Referring now to FIG. 5, an embodiment of a pattern noise processor 88 is 
shown in which a single low-pass filter 90 is disposed downstream of 
subtractor 52. Since the output of subtractor 52 contains both the 
high-frequency and the noise-cancelled, low-frequency components of the 
video signal S, the output of subtractor 52 is applied both to low-pass 
filter 90 and to high-pass filter 58. The clipped high-frequency component 
is added to the noise-cancelled, low-frequency component in adder 63 as in 
the embodiment of FIG. 2. It will be noted that the embodiment of FIG. 5 
reduces the required number of low-pass filters from two to one and 
reduces the number of adders from three to two. 
One disadvantage of the circuit of FIG. 5 arises from the direct 
application of the video signal plus pattern noise S+PN to 1H delay 56. 
With certain types of delay devices, such as, for example, charge coupled 
delay devices, high-amplitude noise spikes in the applied signal may be 
partially attenuated in 1H delay 56 whereas such noise spikes are not 
attenuated in the undelayed signal fed to subtractor 52. When this occurs, 
the two sources of pattern noise differ by the amount of attenuation 
imposed by 1H delay 56. This prevents full cancellation of the pattern 
noise in pattern noise processor 88. The presence of a low-pass filter 
upstream of the delay device may be effective to reduce the amplitude of 
such noise spikes and thus improve the cancellation of pattern noise. 
Otherwise, the operation of the pattern noise processors of FIGS. 2 and 5 
are the same. 
Having described preferred embodiments of the invention with reference to 
the accompanying drawings, it is to be understood that the invention is 
not limited to those precise embodiments, and that various changes and 
modifications may be effected therein by one skilled in the art without 
departing from the scope or spirit of the invention as defined in the 
appended claims.