Technical Field This invention relates to an apparatus within a television (TV) receiver that automatically compensates for signal distortion resulting from transmitter, transmission media, and receiver distortions. In particular, the apparatus pertains to the compensation required for filtering transients both in the transmitting and receiving of high-definition television signals with extended aspect ratio for the recombination of the high-resolution and low- resolution segments of the television picture. Background of the Invention The aspect ratio defines the ratio of the width of the picture to its height. The aspect ratio of a commercial movie theater's screen is at least 5:3, and the conventional United States television picture, as specified by the National Television Standards Committee (NTSC) is 4:3. In addition, a commercial movie theater's picture is of higher resolution than that of conventional United States television. An approach known in the art for providing high-definition television with an extended aspect ratio discloses a television system having a fully compatible high-definition signal with extended aspect ratio information receivable at conventional resolution by conventional TV receivers without auxiliary apparatus with one TV channel carrying the conventional TV signal, while high-frequency luminance and chrominance information plus extended aspect ratio information are provided in a second TV channel. The picture displayed by this TV system consists of a high-resolution center segment and two low- resolution edge segments. Since the human eye tends to focus on the center of the TV screen, the perception is that the viewer is observing a high-resolution extended aspect ratio picture and, in general, does not detect the low-resolution in the two edge' segments. The prior art

discloses a TV receiver which, after reception of the transmitted signal, decodes high- and low-resolution luminance and chrominance information into individual signals and then recombines the low- and high-resolution luminance signals and the low- and high-resolution chrominance signals by gating and summing these signals at the appropriate times.

Whereas, the straight-forward approach utilized by the prior art gives adequate performance where the transmitter and receiver filters are well known and the transmission media is stable, the filters used in the transmitter and receiver as well as the transmission media can cause distortion to appear at the point on the screen where the low-resolution and high-resolution segments come together. One of the reasons for the distortion is the use of filters in both the receiver and transmitter with flat pass-band responses and high stop-band attenuation characteristics. Such filters generally have oscillatory transient responses with overshoots and undershoots. The other processing blocks within the transmitter and receiver also have transient responses. By the time the transmitted signal is received at the decoder portion of the TV receiver, since both the edge and center information have been passed through a number of processing blocks with different transient responses, the abrupt change at the joining point between the low-resolution edge portion of the picture and the high-resolution center portion of the picture has been distorted by the transient response of the different processing units. If this distortion is significant, then the mere gating and summing of the edge and center luminance and chrominance information will leave visible and annoying artifacts appearing at the joint.

Therefore, there exists a need for apparatus that can eliminate or compensate for the transients due to the processing units in both the transmitter and the receiver of a television signal such that the low-resolution edge and high-resolution center segments of a picture in a high-

definition television system with extended aspect ratio can be displayed without annoying artifacts in the proximity of the joint between the different segments. Summary of the Invention The foregoing problem is solved and a technical advance is achieved in accordance with the principles of this invention incorporated in a structural embodiment in which high-definition television display signals with improved aspect ratio information are processed so as to display a picture without distortion at the points where the low- and high-resolution segments of the picture join by the utilization of a test signal that is transmitted during the vertical retrace interval of the TV signal. Advantageously, the test signal is a horizontal line of a known test pattern and a circuit within a TV receiver is responsive to reception of the transmitted test pattern for calculating compensation parameters that can be used to remove distortions introduced during the transmission of the display signals. The calculated compensation parameters are stored in a parameter memory; and then, during the reception of the display signal, the compensation parameters are accessed from the memory and utilized to correct the display signal. In addition, the calculating circuit is responsive to the start of the vertical retrace interval of the display and reception of the test pattern for calculating the compensation parameters.

Advantageously, the test pattern has an edge portion and a center portion and an analog-to-digital converter is responsive to the edge portion for converting the edge signal into a plurality of digital edge samples and converting the center portion into a plurality of digital center samples. In addition, a memory is utilized for storing a plurality of digital constant samples within the television receiver representing the test pattern before transmission. Each compensation parameter is calculated by subtracting one of the digital center samples from one of the digital constant samples and then dividing

this result by one of the edge samples.

Advantageously, as each compensation parameter is calculated, it is stored in a memory. As the display signal is received, the stored compensation parameters are transformed into an analog signal, and the analog signal is multipled with the decoded edge signal and added to the decoded center signal to compensate the display.

Advantageously, before the calculated parameter is stored in the parameter memory, it is compared with the parameter stored during a previous vertical retrace interval. If the difference between the parameters exceeds a predetermined value, the originally stored parameter is retained in the parameter memory. However, if the difference does not exceed the predetermined value, the average between the present calculated parameter and the previous stored parameter is determined and stored in the parameter memory as the new stored parameter. Brief Description of the Drawing

In general, system elements, when first introduced on a figure, are each designated with a number that uses the figure number as the most significant digits of the element number.

FIG. 1 is an illustrative TV picture display on a high-definition television receiver with extended aspect ratio:

FIG. 2 is the circuit for doing the above;

FIG. 3 illustrates in greater details A/D C 240 and arithmetic and memory 241 of FIG. 2;

FIG. 4 illustrates the contents,of memory 307 of FIG. 3;

FIG. 5 illustrates, in flow chart form, a program for controlling the operation of processor 309 of FIG. 3; and

FIG. 6 illustrates, in flow chart form, a modification to the program of FIG. 5 to allow ^" averaging of the compensation parameters stored in parameter memory 310.

Detailed Description

The following describes an apparatus that is used to recombine the high- and low-resolution information segments of a video display with extended aspect ratio. As illustrated in FIG. 1, such a display comprises low- resolution edge information segments 100 and 102, and high- resolution center information segment 101. The recombination apparatus joins the information segments along lines 103 and 104 so that no undesirable artifacts appear in the display along lines 103 and 104. The apparatus functions by using the transmission of a known video signal from a transmitter to a receiver during the vertical retrace time of the receiver. Recombination circuits in the receiver are responsive to the known signal for calculating correction parameters that are subsequently used on a line-by-line basis to compensate the received display edge information for transients introduced by the various transmitter and receiver circuits during the communication of the video signal. A system for receiving a high-definition signal with extended aspect ratio and displaying the picture illustrated in FIG. 1 is shown in FIG. 2. The manner in which the video display information is initially encoded for transmission at the transmitter and then decoded at the receiver illustrated in FIG. 2. The transmitted video signal, Z _&/ comprises high- and low-frequency luminance center information, Y _c _ low-frequency edge luminance information, _{& f} low-frequency center chrominance information, I _{L anα} ; Q _Lf high-frequency center chrominance information L _{H an<} a Q _{H/ an(} a low-frequency

•edge chrominance information, I _{e an} a g _e . Recombination units 213, 215, and 216 are responsive to center and edge information to recombine this information for display by blocks 232 through 235. For example, recombination unit 213 is responsive to the edge luminance signal, Y _on conductor 217 and the center luminance signal, Y _D n conductor 218 to recombine these signals and to tranfer

the resulting signal to adder 233 for display. Recombination unit 213 is illustrated in its major blocks in FIG. 2. Recombination units 215 and 216 are similar in design. With respect to the luminance signals Y _e and

Y _c , recombination unit 213 calculates a series of compensation parameters which, when multiplied with the received edge luminance signal, Y _e , and added to the received center luminance signal, Y _c , compensates for the overshoots and undershoots in Y _e and Y _c caused by the transient responses of the filters in both the transmitter and the receiver as well as those due to the transmission media. After calculation, these parameters are stored internally in arithmetic and memory circuit 241. The calculations are based on the following equations. Since both the edge and center luminance signals have been distorted by filter transients, the original value of the combined luminance test reference signal, Y _Q , before encoding at the transmitter can be recovered at the receiver by the following:

Y _Q (n) = m(n)Y _e (n) + M(n)Y _c (n). (1)

This equation represents the _# signals as. a series of digital samples of the analog luminance signal and Y _Q is limited in bandwidth to the lowest bandwidth of either Y _e or Y _c . ϊ _e (n) and Yς(n) are the received edge and center test reference signals, respectively. The objective of equation 1 is to correct the distortion in Y _e (n) and Y _c (n) caused by transients from all intermediate systems such that their weighted sum is equal to the original value Yø(n). Equation 1 defines an overspecified system, i.e., two variables with only one equation. Given Y _Q (n), Y _e (n), and Y _c (n), an equality can be generated by determining M(n) and m(n) . This can be done by setting

either M(n) or m(n) to an arbitrary, finite, non-zero value and then solving for the other variable. By choosing M(n) = 1, the complexity of an additional multiplication is avoided and the shorter of the segments (the edge segment) is chosen to be scaled.

Setting M(n) = 1 allows equation 1 to be solved for m(n) as follows:

m(n) = V ^{n) " Y} c ⁽ⁿ⁾ (2)

Y _e (n)

Given equation 2, m(n) can be evaluated by knowing the value of Y _Q (n) before encoding at the transmitter. The system calculates m(n) by transmitting Y _{Q as a} known reference signal during the vertical retrace interval. This reference signal illustratively may be a flat field signal representing a gray tone. Since this signal is known, the recombination unit can use the values of this known signal to evaluate the equation _, for m(n).

Recombination unit 213 functions by the analog-to-digital converter (ADC) circuit 240 converting both the Y _an(j

Y _c signals to the digital samples of Y _e (n) and Y _c (n), respectively, for use in solving equation 2. The known signal, Y _Q (Π) , is stored as a series of constants within the arithmetic and memory circuit 241. The latter unit also calculates the formula for m(n) using the stored constant ₀ (n) and the received values for Y _e (n) and ^γ _c (n). During the proper times in the active line scans, arithmetic and memory 241 transmits the parameters, m(n), to the digital-to-analog converter (D/A C) circuit 242 which converts these digital samples into an analog signal

Multiplier circuit 243 is responsive to the output of the

D/A C 242 to multiply these parameters with the Y

signal from delay block 207 thus correcting the received ^γ _e signal. During the edge time, the Yc signal is not allowed to be transmitted to the summing circuit 244 because multiplier 245 is disabled by circuit 241. During the active center time and the transient times, circuit 241 enables the communication of Y to circuit 244. Together, the circuits 243 through 245 implement the equation for Y(n) in real time during the active line time. Elements 240 and 241 of recombination unit 213 are illustrated in greater detail in FIG. 3. A/D C 240 consists of multiplexer 301, A/D 302, and frequency synthesizer 303. Arithmetic and memory unit 241 comprises elements 304 through 312. Edge and center memory 307 stores the digital samples of the Y _anc j _γ signals from A/D C 240 until these samples can be processed by processor 309. Processor 309 utilizes the contents of edge and center memory 307 to calculate the m parameters which it then stores in parameter memory 310. Line counter 304, field detector 305, and address generator 306 are used to generate the control signals for storing the digitized signals Y _e (n) and Yc(n) in edge and center memory 307 and for accessing the m parameters in parameter memory 310 so that these stored values can be utilized D/A C 242 and gate 245. In addition, elements 304, 305, and 306 generate the information to notify processor 309 when the values for the test line have been stored in memory 307.

One frame of display requires the transmission of two fields of information, field 0 and field 1. The two fields are then interlaced to form the_ rame as perceived by the viewer of the TV receiver. The test line is transmitted during the vertical retrace interval of each field; however, the m parameters are calculated once per frame. During each transmission of a test line, multiplexer 301 and A/D 302 convert half of the information available for the Y _{Q and} y _{c s} i _gna ι _s i _nto digital values which are then stored in the edge and center memory 307.

Half of the information contained in the Y _e and Y _c signals are converted during the test line transmitted during the vertical retrace interval of field 0 and the remaining half of the test line information is converted during the transmission of the test line during the vveertical retrace interval of field 1. FIG. 4 illustrates the manner in which this information is stored in edge and center memory 307. Address generator 306 in response to signals from the line counter 304 and field detector 305 generate address signals for transmission on bus 313 and write signals transmitted on conductor 314 for writing the information from A/D 302 into memory 307 as illustrated in FIG. 4. During each test line, the Y _{e an} a γ _c signals are individually written into memory 307 at an illustrative rate of 10.7 MHz.

After the samples of the test line for field 1 have been written into memory 307, address generator 306 transmits a signal via conductor 315 to processor 309. Processor 309 is responsive to the signal on conductor 315 to execute the program illustrated by the flow chart of

FIG. 5. This program performs the calculations defined by the previously mentioned equation 2. Processor 309 accesses the digitized Y _{e an<} a γ _c signals (e(n) and c(n) in FIG. 5) stored in memory 307, via bus 316 and memory controller 308 to calculate the m parameters. As the parameters are calculated, processor 309 stores these parameters in parameter memory 310 again by utilizing bus 316 and memory controller 308. The results of the calculations by processor 309 stored in parameter memory 310 define correction parameters for a complete horizontal line during the active display time. Part of the information stored in parameter memory 310 is the m parameters and information to properly gate the center information into summer 244. The samples in parameter memory 310 corresponding to center time contain a "0" for the m parameters which disables the Y _e signal from being communicated through gate 243 to summer 244 and a "1" for

controlling the communication of the Y _c signal. After translation by voltage translation circuit 312, the latter "1" enables the Y _c signal to be communicated through gate 245 to summer circuit 244. The program illustrated in FIG. 5 is now considered in greater detail. When all of the samples of the test line for field 1 have been written into memory 307, address generator 306 transmits a signal via conductor 315 to processor 309. The program illustrated in FIG. 5, that is controlling the operation of processor 309, detects the transmission of the signal on conductor 315 by continuously checking the BIO (branch on I/O) input of processor 309 for a true state indicated by the presence of a signal on conductor 315. Once the latter signal is detected at the BIO input, the variable containing the sample count, n, is set to 0 in block 502. Once the sample count, n, has been set to 0, the program calculates the values for the correction parameters m(n) and control parameters cc(n). The latter parameters control the operation of gate 245. Blocks 503 through 513 calculate the values for m(n) and cc(n) for the entire test line and store these values in parameter memory 310. The original values of the test line before transmission are known and are stored as a series of constants, t(n), in the internal program memory of processor 309.

For each sample of e(n) and c(n) the following steps are performed. First, the latter samples are read from memory 307 into internal RAM locations of processor 309 by block 503. Then, the intermediate value r is calculated by block 504. The latter calculation performs the subtraction of the center segment sample from the original test line sample as indicated in equation 2.

Next, the value of n is interrogated by block 515 to determine the approximate position within the horizontal line for which a compensation parameter is being calculated. Unless the parameter falls within transition region around joint 103 or 104, as illustrated in FIG. 1,

block 515 determines that it is either in the center or the edge portion of the display illustrated in FIG. 1. Analyzing the largest transient, i.e., that of the edge signal, the transition region for the present sampling 5 frequency may illustratively be defined as extending into the edge portion and the center portion by a number of samples equal to 15 divided by the -3dB bandwidth of the edge signal in MHz. If the samples are determined to be within the center region, then block 510 is executed

10 resulting in the m(n) parameter being set equal to 0 and the control signal, cc(n) , being set equal to "1". Resulting in that during the active display times, the Y signals are inhibited by gate 243 and the Y signals are transmitted through gate 245 to summer 244. If the sample

15 is within the edge segments, block 516 is executed setting the m(n) parameter equal to 1 and the control signal, cc(n) , equal to "0". Resulting in that during the active display time, the Y _{e s} i _gna ι _s are transmitted by gate 243 to summer 244, and Y _c signals are inhibited by gate 245. ^• 20 If block 515 determines that the sample is within

.he transition regions, the edge signal, e(n) , is tested against a threshold value, threshold A, to determine whether or not the edge sample is large enough to be utilized in the calculation of equation 2. If the edge

25 sample is not greater than threshold A, then block 510 is executed having the previously described results. If the edge signal is greater than threshold A, then block 506 is executed resulting in the m(n) being set equal to r/e(n) and cc(n) being set equal to "1". Illustratively,

30 threshold A can have a value to 3% of the peak-to-peak range of the edge signal.

The calculated value m(n) is then checked in block 509 against a maximum value, that it is not too large. If the calculated value is greater 35 than the maximum, then the calculated- value m(n) is set equal to +m _maχ by block 508. Illustratively, m _maχ

may have a value in the range of 2 to 5. After the above calculations and checks have been performed, the resulting values for m(n) and cc(n) are written into parameter memory 310 by block 511. Blocks 512 and 513 then increment n and determine if all these samples have been utilized, then control is transferred back to block 501 ; however, if samples remain to be utilized, control is transferred back to block 501; however, if samples remain to be utilized, control is transferred to block 503. FIG. 6 illustrates a modification to the program of FIG. 5 that allows averaging to be utilized to compensate for the possibility of transient noise causing erroneous values of m(n) to be stored in parameter memory 310. Block 511 of FIG. 5 is replaced with the blocks illustrated in FIG. 6. During the initialization of the system, the latter is detected by block 601 and the calculated values for m(n) and cc(n) are stored into parameter memory 310 as was previously described for FIG. 5. Once stored, the m(n) values are referred to as sm(n). The next time that the parameters are calculated, block 602 is executed. The latter block compares the stored value, sm(n), from parameter memory 310, with the newly calculated value m(n) to determine if the difference is greater than the value D. D may illustratively have a value equal to 25% of the peak-to-peak- range. If the difference is greater than D, which indicates that the present calculated value is incorrect, then block 605 is executed and the value calculated by block 605 is written into parameter memory 310. Block 605 allows the calculated value to slowly change with a number of samples in order to correct an erroneous value. However, if the difference is less than D, then the average is taken between the values of sm(n) and m(n) by block 603, and the average is written into parameter memory 310 by block 604. It is to be understood that the above-described embodiment is merely illustrative of the principles of the invention and that other arrangements may be devised by

those skilled in the art without departing from the spirit and scope of the invention.