Electronic measuring method and apparatus

Disclosed are a method and apparatus for making area measurements of an image on a kinescope screen. Scan lines of the kinescope are divided into a series of pulses by a switching device. The pulses within the image are counted. The number of pulses counted within the image is an indication of the area of the image. The size of the image may be determined in conventional units by comparing the number of pulses counted within the image to the number of pulses known to represent a given area.

TECHNICAL FIELD AND BACKGROUND 
This invention relates to a method and apparatus for electronically 
determining information about areas having a contrasting background in 
brightness by the use of a television system. More specifically, this 
invention relates to a method and apparatus for electronically determining 
the relative size of area which are brought individually into the field of 
view of a television camera, such areas having a contrasting background. 
The method and apparatus according to the present invention has particular 
application in the determination of sizes of bright areas against a dark 
background or vise versa, especially in the case of illuminated areas such 
as holes through a plate, e.g., spinnerette holes. In the instance of 
spinnerette holes, the tiny holes through which liquified polymer is spun 
should be approximately the same size and essentially free from defects 
such as being out of specified shape, clogged, etc. Such defects may cause 
the formation of harsh fiber, broken filaments, improperly formed 
filaments and generally unsatisfactory spinning conditions which lead to 
the generation of slubs and other defects. 
The present invention therefore provides a method and apparatus for 
deriving information such as size of designated areas having a background 
of contrasting brightness. 
More specifically, the present invention provides a method and apparatus 
for determining the size of holes in a plate wherein the holes are bright 
areas with respect to the background, using the video signal from a 
television camera. 
Apparatus and method for insuring that the holes are centered on the 
television screen, thus preventing cumulative drift from affecting 
accuracy of the apparatus and process where used in automatic progression 
of a sequence of holes are disclosed and claimed in my copending 
application filed of even date herewith. 
DISCLOSURE OF INVENTION 
According to the present invention, a method and apparatus is provided for 
making area measurements of portions of an object which are visually 
distinguishable in brightness which comprises 
(a) generating a video signal of at least a single frame duration which 
includes the bright image such that the complete area to be measured is 
encompassed, 
(b) passing only portions of said video signal above a predetermined 
amplitude which correspond to the bright image, 
(c) applying the electrical signal representing the bright image to a 
switching device, one input of which is supplied with a switching signal 
having a frequency of at least 10 times the line scan frequency of the 
video signal to divide the period of scanning represented by the bright 
image into a series of pulses, the duration of the pulse series being 
controlled by the beginning and ending of the signal representing the 
bright image, and 
(d) electrically applying the output signal from the switching device to a 
digital counter, whereby the area of the bright image is measured in terms 
of number of pulses counted.

DETAILED DESCRIPTION OF THE INVENTION 
According to this invention, area measurements are made of illuminated 
portions of objects in the manner illustrated in the drawings. For 
purposes of explanation, the apparatus and method will be described with 
reference to a spinnerette plate which contains a number of holes, 
although it will be obvious to those skilled in the art that the invention 
may be used for other purposes as well. 
Referring to FIG. 1, a spinnerette plate 10, containing a plurality of tiny 
holes 12 is mounted on an assembly having provisions for movement in the 
"X" and "Y" directions so that the plate may be automatically moved from 
position to position for sequential measurements of holes. Apparatus for 
providing such movements will be obvious to those skilled in the art. A 
preferred apparatus (FIGS. 4-7) includes a pair of cooperating motion 
translators mounted at 90.degree. angles to each other so as to cooperate 
in producing movements in the X and Y directions. The motion translators 
cause the plate 10 to travel in precise longitudinal motion and may be 
driven by stepping motors. Thus, by the cooperation of the two motion 
translators, the plate 10 may be moved with precision to predetermined X 
and Y coordinate positions. 
The stepping motors are preferably operated from a computer which has been 
programmed to move the plate 10 in successive steps to the X and Y 
coordinates of selected holes. As well known in the art, a suitable 
computer may be programmed with the location of each hole in the plate. 
Subsequently, the program may be used to return the plate to X and Y 
coordinate positions for sequentially inspecting the holes. 
Plate 10 is supported within the field of view of television camera 40. A 
light source 42 directs a columned beam of light rays 44 at plate 10. For 
convenience, a mirror 46 may be placed in the path of the light rays to 
direct them coaxially with the holes 12. The television camera thus picks 
up the rays of light which pass through holes 12 in a perpendicular 
direction when the plate is correctly positioned. When the apparatus is 
used to measure the size of very tiny holes 12, it may be desirable to use 
a magnifying device to expand the beam of light to occupy a large portion 
(preferably at least 50%) of the field of view of the camera. 
The television camera, as is well known, scans the image formed therein to 
provide an electrical current output (known herein as a "video scan output 
signal" or a "scan output signal"), which in the camera produces a scan 
output signal of high amplitude corresponding to the bright areas and low 
amplitude corresponding to the dark areas. 
The scanning progresses line by line down a frame with the video scan 
output portraying the scanned results of each line serially from the top 
to the bottom of the frame with the scan signals for each line separated 
by line synchronization pulses, and so on from one frame to the next, with 
the frames separated by frame synchronization pulses known as "frame sync 
pulses". The television camera conventionally scans, in one field, every 
second line of those required to completely scan the image, and then scans 
the omitted lines in the next field. 
The video signal generated by camera 40 is fed to a quantizer 60 which 
functions to pass portions of the video signals which are above a 
predetermined amplitude corresponding to the light areas of the picture 
and reject portions of the video signal below the predetermined amplitude 
corresponding to the darker area of the picture. Thus, only that part of 
the picture representing the light area to be measured is passed by the 
quantizer 60. Such quantizers are commercially available, for example, CVI 
Model 606A Video Quantizer, a product of Colorado Video, Inc. The 
quantizer is capable of separating the area to be measured (light area) 
from the rest of the relatively dark picture. In FIG. 3a, there is 
illustrated a picture that would appear at the television monitor. The 
light area 62 representing light passing through the spinnerette hole is 
passed by the quantizer while the darker area 64 is rejected. 
The signal from the quantizer is fed to an amplifier 66 and then to one 
terminal of NAND gate 68. A synchronization (sync) pulse from a sync 
generator 74 is fed to another terminal of NAND gate 68 and then is fed to 
a digital counter 70. Television receiver 72 is used to monitor the 
picture to insure proper positioning of the camera to encompass the 
complete area to be measured and proper size of light areas. NAND gate 68 
is effective to pass a signal when at least one of the input terminals has 
no signal. Conversely, when there is input to all terminals there is no 
output. Thus, the electrical signal representing the bright portion of the 
picture is applied to the NAND gate switching device, and another input is 
supplied with a switching signal from counter 75. 
The sync generator may conveniently be crystal controlled, and produces a 
signal having a frequency of about 20 MHz, which is then divided by two by 
counter 75, the output of which is applied to an input of gate 68. This 
results in a frequency of at least 10 times the line scan frequency of the 
video signal. A signal of 10 MHz pulses becomes available every time a 
signal is available from the quantizer to form the vertical lines. The 
line scans are broken into a series of pulses 74 by the 10 MHz signal 
applied to the gate 68 in the light area 62. Each horizontal line scan is 
converted into a burst of pulses which are available every time the beam 
scans where light from the spinnerette hole is present. It is the counting 
of these pulses, suitably by a digital counter, which gives a measure of 
the size of hole. 
In a conventional television signal there are 525 scan lines per frame. The 
duration of each scan line is about 1/15,750 second. The beginning of each 
scan line is controlled by a sync pulse from the sync generator. In 
accordance with the present invention, a crystal oscillator in the sync 
generator 74 is also used to produce 20 MHz pulses which would at to 
switch each scan line off and on about 600 times, if the entire horizontal 
extent of the line were in a light area. The number of switching pulses 
accumulated in each scan line is counted, preferably by a commercially 
available electronic counter, and the total is used as a reference for a 
hole of a known size. By simple mathematical proportions, the total number 
of switching pulses counted in measurements can be related to sizes of 
other holes. 
Since the video signal is not continuous, but consists of a series of 
scanned images rapidly repeated, it is necessary to separate those scans 
to form a single television picture. To accomplish this, additional 
signals produced by the sync generator are employed to show the beginning 
and end of each complete scan. Specifically, a vertical sync pulse (60 per 
second or twice for each complete television picture) is used. Thus, when 
the counter 70 is activated by applying a first trigger pulse to its 
gating system, the counter accepts the first vertical sync pulse which it 
receives. The counter continues to receive the pulses, skips the second 
vertical sync pulse and when the third is received (indicated a complete 
frame), the counter activates its own gating system to disable itself so 
that no more counts can be accumulated. 
A counting or measuring cycle is initiated when switch 80 is put in 
position A, grounding the input of inverter 82 and causing the inverter 82 
to give an output of positive voltage. This voltage is applied to 
three-decade digital counter 70 and causes the counter to reset to 0. When 
the switch 80 is flipped in the opposite direction into position B, it 
causes flip-flop 84 to be actuated which prevents bouncing of switch 80. 
Once the flip-flop 84 has been flipped by the switch, it applies a voltage 
to counter 86 which divides the pulses by 10, having a binary coded 
decimal output which must be converted into a 10-count signal. When the 
first pulse comes into counter 86 it turns the decoder 88 off of 0 and 
turns on a voltage to position 1. This voltage is translated through 
inverters 90 and 91 which share a common resistor 92 and cause a voltage 
to be developed across that resistor. This voltage ls appled to the third 
input terminal of gate 68 so that there is now a positive signal on all 
three inputs. The video signal from amplifier 66 then is capable of going 
through the gate. The counter signal going into the gate is switching off 
and on. This causes the video signal to be broken into pulses and the 
third signal, which came from decoder 88 through the invertors 90 and 91 
now permits the other two signals to be passed through gate 68 for the 
duration permitted by decoder 88 (two counts), representing one picture 
frame. Since there are two vertical sync pulses for one picture frame, 
counter 70 then receives a video signal which is divided into pulses for 
the duration of one picture frame. The signal which is coming from 
resistor 92 is then turned off and no other signals can come through the 
gate 68. The reading on counter 70 is stored until such time as switch 80 
is flipped back to position A and erased. Voltage is applied in the 
appropriate direction back to flip-flop 84 and causes flip-flop 84 to be 
automatically reset and ready for the next pulse that is applied. When 
switch 80 is repositioned to B again, another sequence of pulses may be 
applied. 
Referring to FIGS. 4 and 5, a spinnerette plate 10, containing a plurality 
of tiny holes 12 is mounted on an assembly having provisions for movement 
in the "X" and "Y" directions so that the plate may be automatically moved 
from position to position for sequential measurements of holes. Apparatus 
for providing such movements will be obvious to those skilled in the art. 
The apparatus illustrated includes a pair of cooperating motion 
translators 14 and 16 mounted at 90.degree. angles relative to each other 
so as to cooperate in producing movements in the X and Y directions. 
Translator 14 is fixed to the top of translator 16. Plate 10 is secured to 
mounting bracket 18 of translator 14. The motion translators 14 and 16 
include movable supports 20 and 22 respectively which are caused to travel 
in precise logitudinal motion along threaded shafts 24 and 26 respectively 
and are driven by stepping motors 28 and 30 respectively. The stepping 
motors 28 and 30 are connected to threaded shafts 24 and 26 respectively 
and designed to provide small rotational movement thereto. Thus, by the 
cooperation of the two motion translators, plate 10 may be moved with 
precision to predetermined X and Y coordinate positions. 
Commercially available motion translators include Series B6000 Unislide, 
sold by Velmex, Inc. of East Bloomfield, N.J. Suitable commercially 
available stepping motors are Slo-Syn Translator Type ST105 Model 
MO93-FD301 available from the Superior Electric Company of Bristol, Conn. 
The stepping motors are preferably operated from a computer which has been 
programmed to move the plate 10 in successive steps to the X and Y 
coordinates of selected holes. As well known in the art, a suitable 
computer may be programmed with the location of each hole in the plate. 
Subsequently, the program may be used to return the plate to X and Y 
coordinate positions for sequentially inspecting the holes. 
Plate 10 is supported within the field of view of television camera 40. In 
a typical application, the supports 20 and 22 have a total free travel of 
six inches in which the supports are propelled on gibbed metal ways by 
means of threaded shafts incorporating 40 threads per inch. The shafts are 
directly connected to the stepping motors connected electrically to step 
1/200 revolutions for each electrical pulse applied to the motor windings. 
As can be readily determined by mathematical analysis of the relationships 
between the amount of circular travel exhibited by the stepping motor for 
a single driving pulse, and the number of threads machined on the lead 
screw, one driving pulse produces a movement of 0.00125 inch travel for 
the table being driven by the screw. Thus by counting the pulses which are 
applied to the motors driving each support, it is possible to precisely 
move each table a predetermined distance along its ways. 
The motors turning the shafts 24 and 26 are supplied with electrical pulses 
applied to their stator windings by means of electrical power amplifiers 
called translators. Small voltage signal pulses ranging from a logical 
zero level of about 1.0 volt to a logical one level of about 4.5 volts are 
applied to the inputs of these translators. Each translator is equipped 
with two inputs. One input when supplied with logic pulses causes the 
motor to rotate in a counterclockwise direction. The second input when 
supplied with logic pulses causes the motor to rotate in a clockwise 
direction. Only one input is activated by logic pulses at the same 
instant, since simultaneous activation of both inputs results in a 
counterproductive reaction which produces no movement of the motor. 
A microcomputer is used to provide the logic pulses which were introduced 
into the inputs of each translator. The microcomputer typically used for 
this purpose is an Intel type 80/30 central processing unit fitted with 
auxiliary memory of 16,000 bytes of RAM memory and auxiliary input and 
output ports sufficient to permit transmitting the electrical pulses 
produced by the computer to the translator inputs. 
Electrical pulses of the nature required to activate the inputs of the 
translators can be produced by any of several ways. A variable frequency 
oscillator can be used. A crystal stabilized oxcillator can also be used. 
Simple manual switching can be used, and the electrical pulses which 
combine to form the numerical output of a digital computer can be used. In 
order that programmed time control of the number and rate of pulse 
production could be achieved, this latter method is preferred. 
The Intel 80/30 microcomputer can be programmed using either of two 
methods. The first used is that of a "high level" language such as 
"basic". This is a commonly used programming language widely used by those 
practicing the computer art. The second language used is dubbed "machine" 
language. Choice of the appropriate language must be based on the end use 
to which the computer is directed. Basic programming language offers 
simplicity in programming but is restricted in that its use requires 
considerable time for the computer to perform its logic duties. Machine 
language is more difficult to employ, but offers great speed of execution 
on the part of the computer. Analysis of the problems of causing the 
stepping motors to propel the tables at acceptable speeds made it evident 
that machine language is preferred to produce the pulses and the counting 
of the pulses to ration out the extent of travel of the tables. Because 
facility of command for the movement of the tables is required, basic 
language is used to program those temporary commands which are required to 
fit the travel pattern of the tables to the tasks which they were required 
to do. In this instance that task is to move a spinnerette of oblong shape 
in both X and Y directions stopping motion to permit a television area 
determining device to determine the area open for each hole drilled or 
otherwise produced in the spinnerette plate. 
Programming consists of determining the extent of travel required to 
translate the spinnerette so that upon stopping of the motion a hole will 
be positioned directly under the area determining device. This is done by 
reducing the interhole dimensions to pulse counts to activate the table 
motors, and programming them into the computer. The rate at which the 
pulses are produced requires adjustment so that initial movement of the 
motor and attached table is effected by slow generation of pulse with a 
gradual increase in pulse production until the maximum pulse rate which is 
acceptable to the motor is attained. Stopping the motor requires the 
reverse action, i.e., gradual decrease of pulse rate until the final pulse 
is delivered. Machine language of the computer to effect this routing is 
prepared and programmed as is well known by those skilled in the art of 
computer programming. 
Upon programming the system described and attempting to use it to determine 
the area of holes drilled into a spinnerette, it may be discovered that 
errors in manufacture of the spinnerette result in the holes being placed 
inexactly, so that precise movement of the tables does not result in 
proper positioning of the holes under the area determining device. To 
determine whether a hole is off center, and if so, by how much, the 
television screen containing the image of the spinnerette hole is 
electronically blanked off so that any image existing on one side of the 
vertical or horizontal center lines are screened off, and the area of the 
remaining image is measured and a comparison made to the area of the total 
image shown on the screen when the image is not blanked off. Since 
centering is required, a condition such that the ratio of blanked off to 
unblanked off image would be equal to one, or equal to one-half of the 
total image would represent the ideal centered condition. Any ratio other 
than the one satisfying this condition is then compared with the ideal and 
the difference registered as insufficient (negative) or excessive 
(positive). The excess or insufficiency of area determined in the blanked 
off image condition then becomes a factor in establishing the number of 
driving pulses to be applied to turn the stepping motors to advance the 
spinnerette to the next hole, or to adjust the motor forward or backward 
to attain perfect centering of the hole under the television camera. The 
positive or negative nature of the area would determine which direction 
the motor would be required to turn in order to attain the desired 
centered condition. 
For rapid processing of the spinnerette, centering should be incorporated 
into the subsequent move to be made after an out of center condition is 
determined by the television camera area determining system. The number of 
pulses to be subtracted or added to the pulses required to move the 
spinnerette to the next hole would then be determined by the computers 
processing of the signals to it and the centering correction applied to 
the next hole. Assuming that manufacturing specifications of the 
spinnerette have not been excessively violated, the next hole should 
arrive under the area determining device reasonably well centered. 
The apparatus and method for determining the deviation from the center of 
the TV screen of hole images will now be described with particular 
reference to FIGS. 8 and 9. 
The electronic systems for sending correction pulses to stepping motors 28 
and 30 is synchronized to a 20 MHz oscillator 100 which drives horizontal 
syn pulse generator 101 and vertical sync pulse generator 160. The 20 MHz 
signal from oscillator 100 is counted and converted into horizontal 
synchronization frequencies of 15,750 Hz by horizontal sync pulse 
generator 101. The 20 MHz pulses are also counted and divided by two by 
decade counter 102 which has a binary coded decimal output. Thus, the 
output of counter 102 is 10 MHz. These 10 MHz pulses are again counted by 
a group of three type 7490 decode counters 104, 106 and 108 which also 
have binary coded decimal outputs. These outputs are decoded by type 7442 
four-to-ten line binary coded decimal-to-decimal decoders 110, 112 and 114 
respectively. The outputs of the decoders are selected to provide a 
decimal output of 3-1-4. 
Each pulse represents one significant digit and place of the number 3-1-4. 
The pulses serve to form a vertical line 105 (see FIG. 10) in the center 
of the TV screen, or each scan line is broken up into 628 dots by the 
imposition of the 10 MHz signal. Vertical line 105 is formed by 
controlling the intensity of the electron beam of the kinescope. 
Modulation of the video signal applied to the kinescope monitor is applied 
at a 10 MHz rate and the modulated video signal is gated by the pulse 
produced from the output of gate 116. Thus, the electron beam of the 
kinescope is turned on to permit a signal pulse of each scan line at a 10 
MHz rate to illuminate the screen at the center. The 3-1-4 digits, when 
activated, provide zero logic pulses which must, in order to be 
accomodated by type 7410 NAND gate 116, be deconverted into logical ones. 
This is accomplished by three type 7404 invertors 118, 120 and 122. When 
all three of the digits 3-1-4 which are selected from the outputs of the 
decoders 110, 112 and 114 provide logical ones to gate 116, the output of 
gate 116 produces a logical zero. This logical zero is fed to a pair of 
type 7400 NAND gates 124 and 126 which are arranged to provide a flip-flop 
128. The imposition of a logical zero on the input of gate 124 causes its 
output to produce a logical one, which in turn activates the input of NAND 
gate 126, causing it to produce an output of a logical zero. There is, in 
effect, a switching action produced between gate 126 and 126. Once they 
have been put into a state where the input from gate 124 has gone to a 
logical zero, gates 124 and 126 tend to stay that way until sucn time as 
they are restored by means of a reset signal derived through type 7404 
invertor 130 from sync generator 101. Upon production of a horizontal sync 
pulse having a logical one, invertor 130 converts this to a logical zero 
and applies it to gate 126 causing flip-flop 128 to reset. The signal 
output from flip-flop 128 is a symmetrical wave in which half the period 
during successive horizontal drive pulses the wave form is logic 1 and the 
remaining half is zero. This wave form is used to switch the video beam of 
the kinescope on or off at the vertical center line 105, as shown in FIG. 
10. 
Oscillator 100 also drives vertical sync pulse generator 160. The 20 MHz 
signal from oxcillator 100 is counted and converted into vertical 
synchronization frequencies of 60 Hz. These 60 Hz pulses are again counted 
by a group of three type 7940 decode counters 132, 134 and 136 which also 
have binary coded decimal outputs. These outputs are decoded by type 7442 
four-through-ten line binary coded decimal-to-decimal decoders 138, 140 
and 142 respectively. The outputs of the decoders are selected to provide 
a decimal output of 1-2-8 to thereby produce pulses which serve to form a 
horizontal line 107 (see FIG. 10) in the center of the TV screen. Thus, 
line 107 of one frame and its counterpart fill-in line of the next frame 
are highlighted on the TV screen. The 1-2-8 digits, when activated, 
provide a zero logic pulse which must, in order to be accomodated by type 
7410 NAND gate 150, be deconverted into logical ones. This is accomplished 
by three type 7404 invertors 144, 146 and 148. When all three of the 
digits 1-2-8 which are selected from the outputs of the decoders 138, 140 
and 142 provide logical ones to gate 150, the output of gate 150 produces 
a logical zero. This logical zero is fed to a pair of type 7400 NAND gates 
154 and 156 which are arranged to provide a flip-flop 152. The imposition 
of a logical zero on the input of gate 154 causes its output to produce a 
logical one, which in turn activates the input of NAND gate 156, causing 
it to produce an output of a logical zero. There is, in effect, a 
switching action produced between gate 154 and 156. Once they have been 
put into a state where the input from gate 154 has gone to a logical zero, 
gates 154 and 156 tend to stay that way until such time as they are 
restored by means of a reset signal derived through type 7404 invertor 158 
from sync generator 160. Upon production of a vertical sync pulse having a 
logical one, invertor 158 converts this to a logical zero and applies it 
to gate 156 causing flip-flop 152 to reset. The signal output from 
flip-flop 152 is a symmetrical wave in which half the period during 
successive horizontal drive pulses the wave form is positive and the 
remaining half it is zero. This wave form is used to switch the video beam 
of the kinescope on or off at the horizontal center line 107, as shown in 
FIG. 10, depending on whether the top or bottom half of the TV screen is 
to be viewed. 
As best shown in FIG. 10, whether "X" or "Y" adjustments are to be made on 
the position of the hole (represented by 169) in the spinnerette plate is 
determined by the ratio of areas of halves of the hole to the complete 
hole. Such areas measurements are made as hereinbefore described. To 
enable the measurement of either horizontal or vertical halves to the 
complete hole, it is necessary to divide the area represented by the hole 
169 into quadrants A, B, C and D. Thus, if a vertical deviation from 
center lne 107 is to be determined, the area of AB or CD would be compared 
to the area of ABCD. On the other hand, if a horizontal deviation from the 
center line 105 is to be determined, the areas of AC or BD would be 
compared to the area ABCD. 
To accomplish such area measurements, adjacent quadrants AB, BD, CD or AC 
must be measured and compared to the complete hole ABCD. These quadrants 
may be selected by the system shown in FIG. 9. Leads 162 and 164 from 
flip-flop 128 on the horizontal adjustment portion are used as inputs to 
type 7400 NAND gates 190 and 188, respectively. Leads 163 and 165 from 
flip-flop 152 on the vertical adjustment portion are used as inputs to 
type 7400 NAND gates 182 and 180 respectively. To select the particular 
quadrants to be viewed for a ratio comparison, a voltage is applied to a 
second input to selected NAND gates 180, 182, 188 and 190. For example, in 
the case where AC is to be viewed, both are in the left half of the hole. 
Consequently, one of the NAND gates 188 or 190 controls the left half. If, 
for example, lead 162 from flip-flop 128 controls the left half, a voltage 
would be applied to the other input 200 of NAND gate 190. Thus, the output 
of gate 190 would be a logical zero. This zero input to type 7400 NAND 
gate 192, along with a logical one from gate 188 (because inputs 164 and 
202 are both zero) results in a logical one output from gate 192. 
Depending on whether a logical one or zero is inposed on the other input 
208 to NAND gate 194, the input to NAND gate 196 from gate 194 will result 
in an output of zero or one to NAND gate 196 to NAND gate 198. 
The gating system from the vertical sync pulse generator is similar to that 
just described for the horizontal zync pulse generator. Thus, leads 163 
and 165 from flip-flop 152 on the vertical adjustment portion are used as 
inputs to type 7400 NAND gates 180 and 182, respectively. For example, in 
the case where AB is to be viewed, both are in the top half of the hole. 
Consequently, one of the NAND gates 180 or 182 controls the top half. If, 
for example, lead 163 from flip-flop 152 controls the top half, a voltage 
would be applied to the other input 204 of NAND gate 182. Thus, the output 
of gate 182 would be a logical zero. This zero input to type 7400 NAND 
gate 184, along with a logical one from gate 180 (because inputs 165 and 
206 are both zero) results in a logical one output from gate 184. 
Depending on whether a logical one or zero is imposed on the other input 
210 to NAND gate 186, the input to NAND gate 196 from gate 186 will result 
in an output of zero or one to NAND gate 196 to NAND gate 198. 
The other input to gate 198, lead 212 is from the area count processor. 
Therefore, even though the area count processor is counting dots in the 
complete hole area, the count being transmitted to the computer or dot 
counter by line 214 for ratio comparision will only be passed through gate 
198 when so directed by the circuitry just described. The result is that 
dot counts in the particular quadrants A, B, C and D selected is 
controlled by the presence or absence of logical zeros or ones on control 
leads 200, 202, 204, 206, 208 and 210. This may be controlled manually or 
by a properly programmed computer. 
FIG. 11 illustrates a simplified circuit for the apparatus and method of 
this invention. If the area to be measured is bright with respect to its 
background, a video signal which includes such area may be isolated by 
passing only the portion of the signal with a high amplitude representing 
the light area. By then chopping up the scan lines into short segments to, 
in effect, produce a series of dots, and counting the dots or they are 
formed, the area may be determined by reference to the number of dots 
representing a known area. Thus, referring to FIG. 11, television camera 
400 is used to photograph an area which contrasts in brightness with its 
background. A timing device 402 provides a means for cutting the scan 
lines into short segments by combining the video signal with a series of 
pulses from timing device 402 at gate 404. The video signal in line 406 is 
continuous and the signal in line 407 from timing device 402 is pulsating. 
By selection of gate 404 to only pass the video signal when there is a 
signal from timing device 402, the video signal emerging from gate 404 
will be cut into short segments. Conversely, gate 404 may be such that it 
will only pass the video signal when there is also a signal from timing 
device 402, in which case the video signal emerging from gate 404 will 
also be pulsating. Counting device 408 receives the pulses which represent 
dots in the bright area, and counts them. 
Television camera 400 is a conventional camera. Timing device 402 may be 
any conventional device or apparatus which will serve to impose a series 
of pulses of selected speed and duration through line 410 to gate 404. 
Although digital timers are preferred, analog timers may be used. The 
timing device is synchronized with camera 400 to begin sending pulses at 
the beginning of a frame of scan lines, and continue through at least one 
field and preferably through the complete frame. The timing device, or 
other suitable circuitry is used to stop counter 408 after a complete set 
of dots have been counted, i.e., after a complete field or frame. Sync 
pulses from camera 400 may be used for stopping and resetting counter 408. 
The invention has been described in detail with particular reference to 
preferred embodiments thereof, but it will be understood that variations 
and modifications can be effected within the spirit and scope of the 
invention.