CA1195767A - Adjustable coring circuit - Google Patents
Adjustable coring circuitInfo
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- CA1195767A CA1195767A CA000423032A CA423032A CA1195767A CA 1195767 A CA1195767 A CA 1195767A CA 000423032 A CA000423032 A CA 000423032A CA 423032 A CA423032 A CA 423032A CA 1195767 A CA1195767 A CA 1195767A
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- signal
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- gain
- amplifier
- peaking
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Abstract
ABSTRACT
Signals to be cored are applied to the inputs of a linear signal amplifier, and of a multistage limiting amplifier having cascaded input and output amplifying stages. A cored version of the signals, corresponding to the difference between a linearly translated version of the signals and a doubly clipped version thereof, is developed by a signal combiner responsive to the outputs of both amplifiers. A variable coring level control voltage controls the distribution of gain between the input and output amplifying stages, substantially without disturbing the overall gain of the limiting amplifier, which is set to match the overall gain of the linear amplifier. In an illustrative embodiment, the signals which are adjustably cored are horizontal peaking signals derived from the received luminance signal in a color television receiver. An automatic peaking control system associated with output of the adjustable coring circuit opposes changes in peaking level that might otherwise accompany coring level adjustment.
Signals to be cored are applied to the inputs of a linear signal amplifier, and of a multistage limiting amplifier having cascaded input and output amplifying stages. A cored version of the signals, corresponding to the difference between a linearly translated version of the signals and a doubly clipped version thereof, is developed by a signal combiner responsive to the outputs of both amplifiers. A variable coring level control voltage controls the distribution of gain between the input and output amplifying stages, substantially without disturbing the overall gain of the limiting amplifier, which is set to match the overall gain of the linear amplifier. In an illustrative embodiment, the signals which are adjustably cored are horizontal peaking signals derived from the received luminance signal in a color television receiver. An automatic peaking control system associated with output of the adjustable coring circuit opposes changes in peaking level that might otherwise accompany coring level adjustment.
Description
7~7 -1- RCA 76,633 ADJUSTABLE CORING CIRCUIT
The present invention relates generally to signal coring circuits, and particularly to novel coring circuits of an adjustable type permitting control of the level of coring, with signal core removal accurately achieved at a plurality of different coring levels.
Coring of a signal (i.e., removing a close-to-average-axis "core" of the signal, by processing the signal with a translator exhibiting a transfer characteristic with a dead zone for close-to-axis signal excursions) is a known signal processing function, occasionally resorted to for noise reduction purposes, as explained, for example, in an article by J. P. Rossi, entitled "Digital Techni~ues for Reducing Television Noise", appearing on pages 134-140 of the March, 1978 issue of the SMPT~ Journal. In certain uses of a coring circuit, a facility for adjusting the level of coring to be effected may be desired. The facility may permit manual adjustment of the coring level (as shown, for example, in an article by R. H. McMann, et al., entitled "Improved Signal Processing Techniques for Color Television Broadcasting", appearing on pages 221-228 of the March 1968 issue of the SMPTE Journal), or may provide for a dynamic adjustment of coring level (as shown, for example, in U. S. Patent No. 4,167,749 - Burrus, where a coring level is varied as a function of the level of noise detected as accompanying a video signal).
The present invention is concerned with the provision of a coring circuit of a type permitting coring level adjustment, but which avoids the need for capacitive elements in its structure, and is conveniently and efficiently realizable in integrated circuit form.
In accordance with the principles of the present invention, a signal to be cored is applied to the input of a linear signal translator and to the input of a non-linear signal translator, the latter comprising a 7~
The present invention relates generally to signal coring circuits, and particularly to novel coring circuits of an adjustable type permitting control of the level of coring, with signal core removal accurately achieved at a plurality of different coring levels.
Coring of a signal (i.e., removing a close-to-average-axis "core" of the signal, by processing the signal with a translator exhibiting a transfer characteristic with a dead zone for close-to-axis signal excursions) is a known signal processing function, occasionally resorted to for noise reduction purposes, as explained, for example, in an article by J. P. Rossi, entitled "Digital Techni~ues for Reducing Television Noise", appearing on pages 134-140 of the March, 1978 issue of the SMPT~ Journal. In certain uses of a coring circuit, a facility for adjusting the level of coring to be effected may be desired. The facility may permit manual adjustment of the coring level (as shown, for example, in an article by R. H. McMann, et al., entitled "Improved Signal Processing Techniques for Color Television Broadcasting", appearing on pages 221-228 of the March 1968 issue of the SMPTE Journal), or may provide for a dynamic adjustment of coring level (as shown, for example, in U. S. Patent No. 4,167,749 - Burrus, where a coring level is varied as a function of the level of noise detected as accompanying a video signal).
The present invention is concerned with the provision of a coring circuit of a type permitting coring level adjustment, but which avoids the need for capacitive elements in its structure, and is conveniently and efficiently realizable in integrated circuit form.
In accordance with the principles of the present invention, a signal to be cored is applied to the input of a linear signal translator and to the input of a non-linear signal translator, the latter comprising a 7~
-2- RCA 76,633 multistage limiting amplifier for developing a doubly limited version of the signals, and exhibiting an overall gain substantially equal to the gain exhibited by the linear signal translator. The limiting amplifier includes first and second signal amplifying stages coupled in cascade for signal amplification purposes. A signal combiner, responsive to outputs of the t~o signal translators, develops a cored version of the signals corresponding to the difference between a linearl~
~0 translated version of the signals and a limited version of the signals. To achieve adjustment of the coring level, means are coupled to the cascaded amplifying stages of the limiting amplifier to alter the distribution of gain therebetween substantially without disturbance of the lS overall gain of the limiting amplifier.
In accordance with an illustrative embodiment of the present inven~ion, the cascaded amplifying stages o the limiting amplifier comprise respective differential amplifiers, each deriving its operating current from the collector electrode of a respective current source transistor. The base-emitter paths of the respective current source transistors are connected in series across a common source of hias. Variation of a variable DC
impedance connected in shunt with the base-emitter path of one of the current source transistors effects the desired coring level control. Illustratively, the variable DC
impedance comprises the collector-emi-tter path of an additional transistor having an adjustably biased base-emitter junction.
In an illustrative use of the present invention, the signal which is subject to adjustable coring is a peaking signal derived from the luminance component of a television signal for use in enhancement of horizontal detail in an image reproduction. In such use of the invention, the adjustably cored peaking signal is desirably thereafter subject to -the action of a closed loop automatic peaking control system so as to substantially preclude the adjustments of coring level .
7~
~0 translated version of the signals and a limited version of the signals. To achieve adjustment of the coring level, means are coupled to the cascaded amplifying stages of the limiting amplifier to alter the distribution of gain therebetween substantially without disturbance of the lS overall gain of the limiting amplifier.
In accordance with an illustrative embodiment of the present inven~ion, the cascaded amplifying stages o the limiting amplifier comprise respective differential amplifiers, each deriving its operating current from the collector electrode of a respective current source transistor. The base-emitter paths of the respective current source transistors are connected in series across a common source of hias. Variation of a variable DC
impedance connected in shunt with the base-emitter path of one of the current source transistors effects the desired coring level control. Illustratively, the variable DC
impedance comprises the collector-emi-tter path of an additional transistor having an adjustably biased base-emitter junction.
In an illustrative use of the present invention, the signal which is subject to adjustable coring is a peaking signal derived from the luminance component of a television signal for use in enhancement of horizontal detail in an image reproduction. In such use of the invention, the adjustably cored peaking signal is desirably thereafter subject to -the action of a closed loop automatic peaking control system so as to substantially preclude the adjustments of coring level .
7~
-3- RCA 76,633 from having undesired effects on the level of peaking attained.
In the drawing:
FIGURE l illustrates, by block diagram representation, a coriny circuit embodyin~ the principles of the present invention;
FIGURE 2 illustrates, partially schematically and partially by block representation, an illustrative implementa-tion of the coring circuit of FIGURE l ~or achievement of adjustable coriny o a peaking signal in a television receiver; and FIGURE 3 illustrates, by block diagram representation, an automatic peaking control system with which the apparatus of FIGURE 2 ma~ desirably be associated.
In the system of FIGURE 1, signals from a signal source 11 are supplied to the inputs of a linear amplifier 13 and of a multistage limiting amplifier 15. The magnitude of the overall gain ~+Gl) provided by the multistage limiting amplifier 15 is equal to the magnitude of the gain (-Gl) of the linear amplifier 13. The outputs of the respective amplifiers are in antiphasal relationship, with the linear amplifier 13, illustratively, providing a net phase inversion, whereas the limiting amplifier 15 is noninverting.
The output of the linear amplifier 13 is a linearly translated version of the input siynals, whereas limiting amplifier 15 serves as a non-linear signal translator providing a doubly clipped version of thP input signals. Summing of the outputs of the respective amplifiers 13, 15 is effected in a signal combiner 17 to form a cored version of the input signals for delivery to a signal utilization circuit 19. The waveform of the cored signals delivered to utilization circuit 19 corresponds to the waveform of the input signals less its central, close-to-axis "core", which has been removed by cancellation in the combiner 17.
In the drawing:
FIGURE l illustrates, by block diagram representation, a coriny circuit embodyin~ the principles of the present invention;
FIGURE 2 illustrates, partially schematically and partially by block representation, an illustrative implementa-tion of the coring circuit of FIGURE l ~or achievement of adjustable coriny o a peaking signal in a television receiver; and FIGURE 3 illustrates, by block diagram representation, an automatic peaking control system with which the apparatus of FIGURE 2 ma~ desirably be associated.
In the system of FIGURE 1, signals from a signal source 11 are supplied to the inputs of a linear amplifier 13 and of a multistage limiting amplifier 15. The magnitude of the overall gain ~+Gl) provided by the multistage limiting amplifier 15 is equal to the magnitude of the gain (-Gl) of the linear amplifier 13. The outputs of the respective amplifiers are in antiphasal relationship, with the linear amplifier 13, illustratively, providing a net phase inversion, whereas the limiting amplifier 15 is noninverting.
The output of the linear amplifier 13 is a linearly translated version of the input siynals, whereas limiting amplifier 15 serves as a non-linear signal translator providing a doubly clipped version of thP input signals. Summing of the outputs of the respective amplifiers 13, 15 is effected in a signal combiner 17 to form a cored version of the input signals for delivery to a signal utilization circuit 19. The waveform of the cored signals delivered to utilization circuit 19 corresponds to the waveform of the input signals less its central, close-to-axis "core", which has been removed by cancellation in the combiner 17.
-4- RCA 76,633 The distribution of gain between cascaded stages of the multistage limiting amplifier 15 is subjeck to adjustment by a gain distribution control circuit 23, in response to a control voltage developed by a variable coring control voltage source 21, substantially without disturbance of the overall gain of limiting amplifier 15.
A convenient techni~ue for so altering the distribution of gain between cascaded stages of a multistage amplifier is disclosed, for example, in U. S. Patent No.
4,464,633, entitled "~nplifier Incorporating Gain Distribution Control For Cascaded Amplifying Stages", issued Auyust 7, 1984.
As the distribution of gain between cascaded input and output stages of amplifier 15 is altered in lS response to a variation of the control voltage supplied by source 21, the relative magnitude of the`core subject to removal in combiner 17 is altered. That is, the depth or level of coring of the input signals is adjusted in response to a variation of the coring control voltage.
gain distribution change that elevates input stage gain results in a clipping by the output stage that is closer to the axis, and thus reduces the coring level.
Conversely, a gain distribution change that depresses input stage gain increases the coring level. Maintenance of the overall gain of amplifier 15 substantially constant in the face of the gain distribution changes, however, assures the matching relationship ~etween portions of the waveforms of the inputs to combiner 17 that is required for accurate cancellation therein so as to effect coring at the selected level.
In FIGURE 2, an illustrative embodiment of the coring system of FIGURE 1 is sho~7n in schematic detail, performing the function of adjus-table coring of a horizontal peaking signal in a television receiver. In the FIGURE 2 embodiment, a differential amplifier 40 serves as the linear amplifier of the FIGURE 1 system, and differential amplifiers 50 and 60 serve as the cascaded 7~7
A convenient techni~ue for so altering the distribution of gain between cascaded stages of a multistage amplifier is disclosed, for example, in U. S. Patent No.
4,464,633, entitled "~nplifier Incorporating Gain Distribution Control For Cascaded Amplifying Stages", issued Auyust 7, 1984.
As the distribution of gain between cascaded input and output stages of amplifier 15 is altered in lS response to a variation of the control voltage supplied by source 21, the relative magnitude of the`core subject to removal in combiner 17 is altered. That is, the depth or level of coring of the input signals is adjusted in response to a variation of the coring control voltage.
gain distribution change that elevates input stage gain results in a clipping by the output stage that is closer to the axis, and thus reduces the coring level.
Conversely, a gain distribution change that depresses input stage gain increases the coring level. Maintenance of the overall gain of amplifier 15 substantially constant in the face of the gain distribution changes, however, assures the matching relationship ~etween portions of the waveforms of the inputs to combiner 17 that is required for accurate cancellation therein so as to effect coring at the selected level.
In FIGURE 2, an illustrative embodiment of the coring system of FIGURE 1 is sho~7n in schematic detail, performing the function of adjus-table coring of a horizontal peaking signal in a television receiver. In the FIGURE 2 embodiment, a differential amplifier 40 serves as the linear amplifier of the FIGURE 1 system, and differential amplifiers 50 and 60 serve as the cascaded 7~7
5- RCA 76,633 input and output stages of the multistage limiting amplifier of the FIGURE 1 system.
To develop the peaking signal which is to be processed by circuitry en~odying -the principles of the S present inven~ion, the output of a luminance sign~l source 25 (e.g., in a color television receiver use, constituted by the luminance siqnal output of the receiver's comb filter) is coupled via a resistor 27 to the input terminal (L) of a delay line 29. Illustratively, the delay line 29 is a ~ideband device exhibiting a linear phase characteristic over the frequency band occupied by the signals from source 25 (e.g., extending to 4.0 M~Iz.), and provides a signal delay of 140 nanoseconds. The input end of delay line 29 is terminated (e.g., through the aid of resistor 27) in an impedance substantially matching its characteristic impedance, whereas the output end of the delay line (at terminal L') is misterminated to obtain a reflective effect. The signals appearing at the respective ends of the delay line 29 are thus: (a) a once-delayed luminance signal at terminal L', and (b) the sum of an undelayed luminance signal and a twice-delayed luminance signal at terminal L. The difference between the respective signals at terminals L and L' corresponds to an appropriate horizontal peaking signal for addition to the luminance signal to enhance its horizontal detail (by effectively boosting luminance components in a freguency range from 1.75 MHz. to 5.25 MHz., -6 db points, with a maximum boost at 3.5 MHz.).
Differential amplifier 40, accepting signals from terminals L and L' at its respective differen-tial inputs, provides a linear amplification channel for such a peaking signal. Amplifier 40 includes a pair of NPN
transistors 41, 43 with interconnected emi-tter electrodes returned to a point of reference potential (e.g., ground) via the collector-emitter path of an NPN current source transistor 45 in series with emitter resistor 46. The base electrode of transistor 45 is connected to the
To develop the peaking signal which is to be processed by circuitry en~odying -the principles of the S present inven~ion, the output of a luminance sign~l source 25 (e.g., in a color television receiver use, constituted by the luminance siqnal output of the receiver's comb filter) is coupled via a resistor 27 to the input terminal (L) of a delay line 29. Illustratively, the delay line 29 is a ~ideband device exhibiting a linear phase characteristic over the frequency band occupied by the signals from source 25 (e.g., extending to 4.0 M~Iz.), and provides a signal delay of 140 nanoseconds. The input end of delay line 29 is terminated (e.g., through the aid of resistor 27) in an impedance substantially matching its characteristic impedance, whereas the output end of the delay line (at terminal L') is misterminated to obtain a reflective effect. The signals appearing at the respective ends of the delay line 29 are thus: (a) a once-delayed luminance signal at terminal L', and (b) the sum of an undelayed luminance signal and a twice-delayed luminance signal at terminal L. The difference between the respective signals at terminals L and L' corresponds to an appropriate horizontal peaking signal for addition to the luminance signal to enhance its horizontal detail (by effectively boosting luminance components in a freguency range from 1.75 MHz. to 5.25 MHz., -6 db points, with a maximum boost at 3.5 MHz.).
Differential amplifier 40, accepting signals from terminals L and L' at its respective differen-tial inputs, provides a linear amplification channel for such a peaking signal. Amplifier 40 includes a pair of NPN
transistors 41, 43 with interconnected emi-tter electrodes returned to a point of reference potential (e.g., ground) via the collector-emitter path of an NPN current source transistor 45 in series with emitter resistor 46. The base electrode of transistor 45 is connected to the
-6- RCA 76,633 positive terminal (~1.2 V.) of a bias potential supply to establish a desired operating current for amplifier 40.
Signals from terminal L' are supplied -to the base electrode of transistor 41 via the base-emitter path of an NPN emitter-follower transistor 34 and a series coupling resistor 36. The collector electrode of transistor 34 is directly connected to the posi-tive terminal (~Vcc) o~ an operating potential supply, while the emitter electrode of transistor 34 is returned to ground via the collector-emitter path of a current source transistor 35 (having its base electrode connected to the +1.2 V. bias supply terminal) in series with emitter resistor 26. Signals from terminal L are supplied tG the base electrode of transistor 43 via the base-emitter path of an NPN emitter-~ollower transistor 30 and a series coupling resistor 32. The collector electrode of transistor 30 is directly connected to the +Vcc supply terminal, while the emitter electrode of transistor 30 is returned to ground via the collector-emitter path of a current source transistor 31 (having its base electrode connected to the ~1.2 V. bias supply terminal) in series with emitter resistor 28. While direct connections are illustrated between the respective terminals L, L' and the bases of emitter-follower transistors 30, 34, additional emitter-followers (not shown) may desirably be interposed in the respective connections to elevate the impedances`
presented to the respective terminals.
A resistor 38 interconnects the base electrodes of transistors 41, 43, and cooperates with the coupling resistors 36, 32 to introduce a degree of attenuation of the input signals that ensures that the maximum signal difference between base potentials is accommodated wi-thin the linear signal handling range of amplifier 40. The respective collector electrodes of transistors 41 and 43 are linked to the positive terminal of an operating potential supply by respective loads (not shown) which are shared by the limiting amplifier's ou.tputsO The respective collector currents of transistors 41 and 43
Signals from terminal L' are supplied -to the base electrode of transistor 41 via the base-emitter path of an NPN emitter-follower transistor 34 and a series coupling resistor 36. The collector electrode of transistor 34 is directly connected to the posi-tive terminal (~Vcc) o~ an operating potential supply, while the emitter electrode of transistor 34 is returned to ground via the collector-emitter path of a current source transistor 35 (having its base electrode connected to the +1.2 V. bias supply terminal) in series with emitter resistor 26. Signals from terminal L are supplied tG the base electrode of transistor 43 via the base-emitter path of an NPN emitter-~ollower transistor 30 and a series coupling resistor 32. The collector electrode of transistor 30 is directly connected to the +Vcc supply terminal, while the emitter electrode of transistor 30 is returned to ground via the collector-emitter path of a current source transistor 31 (having its base electrode connected to the ~1.2 V. bias supply terminal) in series with emitter resistor 28. While direct connections are illustrated between the respective terminals L, L' and the bases of emitter-follower transistors 30, 34, additional emitter-followers (not shown) may desirably be interposed in the respective connections to elevate the impedances`
presented to the respective terminals.
A resistor 38 interconnects the base electrodes of transistors 41, 43, and cooperates with the coupling resistors 36, 32 to introduce a degree of attenuation of the input signals that ensures that the maximum signal difference between base potentials is accommodated wi-thin the linear signal handling range of amplifier 40. The respective collector electrodes of transistors 41 and 43 are linked to the positive terminal of an operating potential supply by respective loads (not shown) which are shared by the limiting amplifier's ou.tputsO The respective collector currents of transistors 41 and 43
-7- RCA 76,633 vary in accordance with oppositely phased versions of the peaking signals.
Differential amplifier 50, accepting signals from terminal L and L' at its respective differential inputs, serves as the input stage of a limiting amplifier providing a no~-linear amplification channel for the peaking signal. Amplifier 50 includes a pair of NPN
transistors 51, 53 with interconnected emitter electrodes returned to ground via the collector-emitter path of an NPN current source transistor 55. Signals from terminal L', appearing at the output of emitter-follower transistor 34, are supplied to the base electrode of -transistor 51 via a series coupling resistor 37, Signals from terminal L, appearing at the output of emitter-follower transistor 30, are supplied to the base electrode of transistor 53 via a series coupling resistor 33. A resistor 39 interconnects the base electrodes of transistors 51 and 53. The input signal attenuation provided by the network of resistors 37, 39, 33 is less than the attenuation provided by the linear amplifier network (36, 38, 32), and permits the maximum signal swing between bases to exceed the linear signal handling range of amplifier 50.
The collector electrodes of transistors 51 and 53 are individually connected b~ respective load resistors (57, 59) to the positive terminal (+4.0 V.) of an opera-ting potential supply. Oppositely phased pea~ing signals (with maximum excursions clipped) appear across the respective load resistors 57 and 59.
Differential amplifier 60, serving as the output stage of the limiting amplifier and providing further clipping of the peaking signals, includes a pair of NPN
transistors 61 and 63 with emitter electrodes connected to the collector electrode of a current source transistor 65.
The emitter electrode of transistor 65 is returned to ground via the base-emitter path of current source transistor 55. The base electrode of transistor 61 is directly connected to the collectox elec~rode of transistor 51 of the input stage, while the base electrode 57~7
Differential amplifier 50, accepting signals from terminal L and L' at its respective differential inputs, serves as the input stage of a limiting amplifier providing a no~-linear amplification channel for the peaking signal. Amplifier 50 includes a pair of NPN
transistors 51, 53 with interconnected emitter electrodes returned to ground via the collector-emitter path of an NPN current source transistor 55. Signals from terminal L', appearing at the output of emitter-follower transistor 34, are supplied to the base electrode of -transistor 51 via a series coupling resistor 37, Signals from terminal L, appearing at the output of emitter-follower transistor 30, are supplied to the base electrode of transistor 53 via a series coupling resistor 33. A resistor 39 interconnects the base electrodes of transistors 51 and 53. The input signal attenuation provided by the network of resistors 37, 39, 33 is less than the attenuation provided by the linear amplifier network (36, 38, 32), and permits the maximum signal swing between bases to exceed the linear signal handling range of amplifier 50.
The collector electrodes of transistors 51 and 53 are individually connected b~ respective load resistors (57, 59) to the positive terminal (+4.0 V.) of an opera-ting potential supply. Oppositely phased pea~ing signals (with maximum excursions clipped) appear across the respective load resistors 57 and 59.
Differential amplifier 60, serving as the output stage of the limiting amplifier and providing further clipping of the peaking signals, includes a pair of NPN
transistors 61 and 63 with emitter electrodes connected to the collector electrode of a current source transistor 65.
The emitter electrode of transistor 65 is returned to ground via the base-emitter path of current source transistor 55. The base electrode of transistor 61 is directly connected to the collectox elec~rode of transistor 51 of the input stage, while the base electrode 57~7
-8- RCA 76,633 of transistor 63 iS directly connected to the collector electrode of transistor 53 of the input stage.
The collector electrode of transistor 61 iS
directly connected to the collector electrode of transistor 41 of the linear amplifier so that the summed collector currents of transistors 41 and 61 fo.rm a cored peaking signal current (Ip'). The collector electrode of transistor 63 iS directly connected to the collector electrode of transistor ~3 of the linear amplifier so tha-t the summed collector currents of -transistors 43 and 63 form a cored peaking signal current Ip (an oppositely phased version of Ip').
A resistor 66 is connected between the positive terminal (+3.2 V.) of a bias potential supply and the 15 - anode of a diode 67, the cathode of which is directly connected to the anode of a second diode 68. The cathode of diode 68 iS directly connected to ground, so that the pair o~ diodes 67, 68 are forward biased by the bias potential supply. The anode of diode 67 iS directly connected to the base electrode of current source transistor 65, so that the voltage appearing across the diode pair (67, 68) is applied across the serially disposed base-emitter paths of current source transistors ~5, 55 to forward bias their base-emitter junctions.
The collector electrode of an additional NPN
transistor 71 is directly connected to the base electrode of transistor 55. The emitter electrode of transistor 71 is directly connected to ground, disposing the collector-emitter path of transistor 71 directly in shunt with the base-emitter path of the input stage's current source transistor 55.
A coring control voltage input terminal CC is connected to the base electrode of an NPN emitter-follower transistor 75 (having its collector electrode directly connected to the ~Vcc supply terminal). The emitter electrode of transistor 75 is connected via resistor 73 to the base electrode of transistor 71, and to the anode of a diode 72. The cathode of diode 72 is directly connected
The collector electrode of transistor 61 iS
directly connected to the collector electrode of transistor 41 of the linear amplifier so that the summed collector currents of transistors 41 and 61 fo.rm a cored peaking signal current (Ip'). The collector electrode of transistor 63 iS directly connected to the collector electrode of transistor ~3 of the linear amplifier so tha-t the summed collector currents of -transistors 43 and 63 form a cored peaking signal current Ip (an oppositely phased version of Ip').
A resistor 66 is connected between the positive terminal (+3.2 V.) of a bias potential supply and the 15 - anode of a diode 67, the cathode of which is directly connected to the anode of a second diode 68. The cathode of diode 68 iS directly connected to ground, so that the pair o~ diodes 67, 68 are forward biased by the bias potential supply. The anode of diode 67 iS directly connected to the base electrode of current source transistor 65, so that the voltage appearing across the diode pair (67, 68) is applied across the serially disposed base-emitter paths of current source transistors ~5, 55 to forward bias their base-emitter junctions.
The collector electrode of an additional NPN
transistor 71 is directly connected to the base electrode of transistor 55. The emitter electrode of transistor 71 is directly connected to ground, disposing the collector-emitter path of transistor 71 directly in shunt with the base-emitter path of the input stage's current source transistor 55.
A coring control voltage input terminal CC is connected to the base electrode of an NPN emitter-follower transistor 75 (having its collector electrode directly connected to the ~Vcc supply terminal). The emitter electrode of transistor 75 is connected via resistor 73 to the base electrode of transistor 71, and to the anode of a diode 72. The cathode of diode 72 is directly connected
-9- RCA 76,633 to ground, disposing diode 72 directly in shunt with the base-emitter path of transistor 71. A posi-tive coring control voltage applied to terminal CC controls the biasing of transistor 71 to vary the conductance of its collector-emitter path and thereby adjust the level of coring attained in the output signal current Ip and Ip'.
The variable coring control voltage may be provided by a manual control source (as in the aforementioned McMann, et al. article, for example) or a dynamic control source (as in the aforementioned ~urrus patent, for example).
The base-emitter path of transistor 65 forms a voltage divider with the parallel combination of (a) the base-emitter path of transistor 55, and (b) the collector-emitter path of transistor 71, to effect a division of the bias voltage appearing across the series-connected diodes 67, 68, with the division ratio dependent upon the conductance of transi`stor 71. When the shunting impedance presented by transistor 71 decreases (due to an increase in the coring control voltage), the base-emitter voltage (Vbe) of current source transistor 55 decreases, accompanied by a complementary increase of the base-emitter voltage of current source transistor 65.
~hen the shunting impedance presented by transistor 71 increases (due to a decrease in the coring control voltage), the Vbe of transistor 55 increases, accompanied by a complemen-tary decrease of the Vbe of transis-tor 65;
The consequence of a variation of the coring control voltage is thus an introduction of complementary variations in the operating currents of differential amplifiers 50 and 60, and, hence, complementary varia-tions of the respective gains of the two cascaded stages of the limiting amplifier. With variations of the DC impedance presented by transistor 71 having a negligible effect on the bias voltage appearing across diodes 67, 68, the overall gain of the limiting amplifier, proportional to the product of the magnitudes of the respective stage's operating current, remains substantially undisturbed as the distribution of gain between respective stages is ,.
~57~7
The variable coring control voltage may be provided by a manual control source (as in the aforementioned McMann, et al. article, for example) or a dynamic control source (as in the aforementioned ~urrus patent, for example).
The base-emitter path of transistor 65 forms a voltage divider with the parallel combination of (a) the base-emitter path of transistor 55, and (b) the collector-emitter path of transistor 71, to effect a division of the bias voltage appearing across the series-connected diodes 67, 68, with the division ratio dependent upon the conductance of transi`stor 71. When the shunting impedance presented by transistor 71 decreases (due to an increase in the coring control voltage), the base-emitter voltage (Vbe) of current source transistor 55 decreases, accompanied by a complementary increase of the base-emitter voltage of current source transistor 65.
~hen the shunting impedance presented by transistor 71 increases (due to a decrease in the coring control voltage), the Vbe of transistor 55 increases, accompanied by a complemen-tary decrease of the Vbe of transis-tor 65;
The consequence of a variation of the coring control voltage is thus an introduction of complementary variations in the operating currents of differential amplifiers 50 and 60, and, hence, complementary varia-tions of the respective gains of the two cascaded stages of the limiting amplifier. With variations of the DC impedance presented by transistor 71 having a negligible effect on the bias voltage appearing across diodes 67, 68, the overall gain of the limiting amplifier, proportional to the product of the magnitudes of the respective stage's operating current, remains substantially undisturbed as the distribution of gain between respective stages is ,.
~57~7
-10- RCA 76,633 varied. For accuracy of coring, this undisturbed magnitude of overall gain is set so that the gains of the respective non-linear and linear amplification channels are substantially identical.
A gain distribution change (caused by a decrease in coring control voltage) that elevates input stage (50) gain results in a clipping by the output stage (60) that is closer to the axis, and thus reduces the coring level.
Conversely, a gain distribution change (caused by an 1~0 increase in coring control voltage) that depresses input stage gain increases the coring level.
FIGURE 3 illustrates additional signal processing apparatus with which the peaking signal corer of FIGURE 2 may be desirably associated. In FIGURE 3, the (push-pull) cored peaking signal outputs (Ip and Ip') of the FIGURE 2 system are supplied as signal inputs to a gain controlled peaking signal amplifier 101. Amplifier 101 translates the cored peaking signals with a gain (or attenuation) determined by a control voltage applied to a peaking control terminal PC.
The push-pull outputs of amplifier 101 are summed with the push-pull outputs of a luminance signal amplifier 105, responsive to the delayed luminance signals at terminal L' (FIGURE 2), in a signal combiner 103 to form push-pull versions of a peaked luminance signal for application to a peaked luminance signal amplifier 107.
Amplifier 107 converts -the push-pull peaked luminance signal inputs to single-ended form at output terminal O, from ~Jhich terminal the peaked luminance signal may be delivered, for example, to a color receiver's matrix circuits for combination with respective color-difference signals.
The output of amplifier 107 is also applied to the input of a bandpass amplifier 109 for automatic peaking control purposes. Illustratively exhibiting a passband of approximately 1 M~lz. bandwidth centered about a frequency of approximately 2 ~Hz., amplifier 109 delivers the components of the peaked luminance signal 7~7 ~ RCA 76,633 falling within its passband to a peak detector 110, ~7hich develops a control voltage proportional to the amplitude of the delivered components. This control voltage is applied to terminal PC to control the magnitude of the peaking signals supplied to con~iner 103 in a sense opposing changes in the amplitude of said delivered components. Reference may be made to U.s. Patent No.
4,399,'160, issued August 16, 1983, or a more detailed explanation of the operation of such an automatic peaking control system, and examples of advantageous circuitry for implementing the functions o~
the elements 101, 103, 105, 107, 109 and 110 (as well as associating a manual peaking control therewith).
An advantage of associating the apparatus of FIGURE 3 with the adjustable coring system of FIGURE 2 resides in the substantial avoidance of any adverse effects on peaking le~el when the coring level is`
adjusted. To illustrate this point, consider, for example, that a coring control voltage chan~e is made to increase the coring level for purposes of increased removal of noise components from the peaking signal outputs of the FIGURE 2 system. One accompanying consequence of such a greater core removal is a reduction of the amplitude of the retained peaking signal components in outputs Ip and Ip'. The automatic peaking control system of FIGURE 3, however, will tend to oppose any weakening of peaking effects that such amplitude reduction might otherwise cause by in-troducing a compensatory change in the gain o~ amplifier 101.
An illustrative set of values for circuit parameters of the FIGURE 2 system is, as ~ollows:
Resistors 26, 28.............. 2 kilohms Resistor 27................... 680 ohms Resistors 32, 36.............. 2.4 kiloh~s Resistors 33, 37.............. 470 ohms Resistor 38................... 1000 ohms Resistor 39................... 4.7 kilohms 5~
-12- RCA 76,633 Resistors 46, 57, 59.......... 500 ohms Resistor 66................... 13.3 kilohms Resistor 73................... 25 kilohms Potential (+Vcc).............. 11.2 volts
A gain distribution change (caused by a decrease in coring control voltage) that elevates input stage (50) gain results in a clipping by the output stage (60) that is closer to the axis, and thus reduces the coring level.
Conversely, a gain distribution change (caused by an 1~0 increase in coring control voltage) that depresses input stage gain increases the coring level.
FIGURE 3 illustrates additional signal processing apparatus with which the peaking signal corer of FIGURE 2 may be desirably associated. In FIGURE 3, the (push-pull) cored peaking signal outputs (Ip and Ip') of the FIGURE 2 system are supplied as signal inputs to a gain controlled peaking signal amplifier 101. Amplifier 101 translates the cored peaking signals with a gain (or attenuation) determined by a control voltage applied to a peaking control terminal PC.
The push-pull outputs of amplifier 101 are summed with the push-pull outputs of a luminance signal amplifier 105, responsive to the delayed luminance signals at terminal L' (FIGURE 2), in a signal combiner 103 to form push-pull versions of a peaked luminance signal for application to a peaked luminance signal amplifier 107.
Amplifier 107 converts -the push-pull peaked luminance signal inputs to single-ended form at output terminal O, from ~Jhich terminal the peaked luminance signal may be delivered, for example, to a color receiver's matrix circuits for combination with respective color-difference signals.
The output of amplifier 107 is also applied to the input of a bandpass amplifier 109 for automatic peaking control purposes. Illustratively exhibiting a passband of approximately 1 M~lz. bandwidth centered about a frequency of approximately 2 ~Hz., amplifier 109 delivers the components of the peaked luminance signal 7~7 ~ RCA 76,633 falling within its passband to a peak detector 110, ~7hich develops a control voltage proportional to the amplitude of the delivered components. This control voltage is applied to terminal PC to control the magnitude of the peaking signals supplied to con~iner 103 in a sense opposing changes in the amplitude of said delivered components. Reference may be made to U.s. Patent No.
4,399,'160, issued August 16, 1983, or a more detailed explanation of the operation of such an automatic peaking control system, and examples of advantageous circuitry for implementing the functions o~
the elements 101, 103, 105, 107, 109 and 110 (as well as associating a manual peaking control therewith).
An advantage of associating the apparatus of FIGURE 3 with the adjustable coring system of FIGURE 2 resides in the substantial avoidance of any adverse effects on peaking le~el when the coring level is`
adjusted. To illustrate this point, consider, for example, that a coring control voltage chan~e is made to increase the coring level for purposes of increased removal of noise components from the peaking signal outputs of the FIGURE 2 system. One accompanying consequence of such a greater core removal is a reduction of the amplitude of the retained peaking signal components in outputs Ip and Ip'. The automatic peaking control system of FIGURE 3, however, will tend to oppose any weakening of peaking effects that such amplitude reduction might otherwise cause by in-troducing a compensatory change in the gain o~ amplifier 101.
An illustrative set of values for circuit parameters of the FIGURE 2 system is, as ~ollows:
Resistors 26, 28.............. 2 kilohms Resistor 27................... 680 ohms Resistors 32, 36.............. 2.4 kiloh~s Resistors 33, 37.............. 470 ohms Resistor 38................... 1000 ohms Resistor 39................... 4.7 kilohms 5~
-12- RCA 76,633 Resistors 46, 57, 59.......... 500 ohms Resistor 66................... 13.3 kilohms Resistor 73................... 25 kilohms Potential (+Vcc).............. 11.2 volts
Claims (7)
1. A system for effecting an adjustable amount of coring of signals derived from a source comprising:
first signal translating means, having an input coupled to said source, for linearly translating said signals;
second signal translating means, having an input coupled to said source, for non-linearly translating said signals; said second signal translating means comprising a multistage limiting amplifier for developing a limited version of said signals, said limiting amplifier including first and second signal amplifying stages coupled in cascade, and exhibiting an overall gain substantially equal to the gain exhibited by said first signal translating means;
means, responsive to the outputs of said first and second signal translating means, for developing a cored version of said signals corresponding to the difference between a linearly translated version of said signals and a limited version of said signals; and means, coupled to said first and second signal amplifying stages, for selectively altering the distribution of gain between said first and second signal amplifying stages substantially without disturbance of said overall gain of said limiting amplifier.
first signal translating means, having an input coupled to said source, for linearly translating said signals;
second signal translating means, having an input coupled to said source, for non-linearly translating said signals; said second signal translating means comprising a multistage limiting amplifier for developing a limited version of said signals, said limiting amplifier including first and second signal amplifying stages coupled in cascade, and exhibiting an overall gain substantially equal to the gain exhibited by said first signal translating means;
means, responsive to the outputs of said first and second signal translating means, for developing a cored version of said signals corresponding to the difference between a linearly translated version of said signals and a limited version of said signals; and means, coupled to said first and second signal amplifying stages, for selectively altering the distribution of gain between said first and second signal amplifying stages substantially without disturbance of said overall gain of said limiting amplifier.
2. Apparatus in accordance with claim 1 wherein one of said signal translating means, to the exclusion of the other, subjects said signals to a net phase inversion, and wherein said cored signal developing means comprises means for summing outputs of said first and second signal translating means.
3. Apparatus in accordance with claim 1, for use with a source of luminance signals, wherein the signals translated by said first and second signal translating means comprise peaking signals derived from said luminance signal source.
4. Apparatus in accordance with claim 2, also including:
a gain controlled peaking signal amplifier responsive to the output of said cored version developing means;
means for combining the output of said gain controlled peaking signal amplifier with luminance signals derived from said source to form a peaked luminance signal output; and means, responsive to said peaked luminance signal output, for controlling the gain of said peaking signal amplifier.
a gain controlled peaking signal amplifier responsive to the output of said cored version developing means;
means for combining the output of said gain controlled peaking signal amplifier with luminance signals derived from said source to form a peaked luminance signal output; and means, responsive to said peaked luminance signal output, for controlling the gain of said peaking signal amplifier.
5. Apparatus in accordance with claim 4, wherein said gain controlling means includes a frequency selective amplifier having an input coupled to receive said peaked luminance signal output, said frequency selective amplifier exhibiting a pass band encompassing a high frequency portion of the frequency spectrum occupied by said luminance signals;
and a peak detector responsive to the output of said frequency selective amplifier for developing a gain control voltage.
and a peak detector responsive to the output of said frequency selective amplifier for developing a gain control voltage.
6. In a television receiver including a source of luminance signals, apparatus comprising, in combination:
a delay line having its input coupled to said source of luminance signals;
a linear signal translator; said linear signal translator comprising a first differential amplifier having a pair of inputs coupled to be responsive to signals appearing at the input of said delay line, and to signals appearing at the output of said delay line, respectively;
a non-linear signal translator; said non-linear signal translator comprising a limiting amplifier including second and third differential amplifiers coupled in cascade, said second differential amplifier having a pair of inputs coupled to be responsive to signals appearing at the input of said delay line, and to signals appearing at the output of said delay line, respectively;
means, coupled to said second and third differen-tial amplifiers, for simultaneously varying the gains of said second and third differential amplifiers in mutually opposite directions; the overall gain of said non-linear signal translator being independent of the operation of said gain varying means and substantially equal to the gain of said linear signal translator;
means for combining the outputs of said linear signal translator and said non-linear signal translator to form a cored peaking signal, with the level of coring dependent upon the operation of said gain varying means.
a delay line having its input coupled to said source of luminance signals;
a linear signal translator; said linear signal translator comprising a first differential amplifier having a pair of inputs coupled to be responsive to signals appearing at the input of said delay line, and to signals appearing at the output of said delay line, respectively;
a non-linear signal translator; said non-linear signal translator comprising a limiting amplifier including second and third differential amplifiers coupled in cascade, said second differential amplifier having a pair of inputs coupled to be responsive to signals appearing at the input of said delay line, and to signals appearing at the output of said delay line, respectively;
means, coupled to said second and third differen-tial amplifiers, for simultaneously varying the gains of said second and third differential amplifiers in mutually opposite directions; the overall gain of said non-linear signal translator being independent of the operation of said gain varying means and substantially equal to the gain of said linear signal translator;
means for combining the outputs of said linear signal translator and said non-linear signal translator to form a cored peaking signal, with the level of coring dependent upon the operation of said gain varying means.
7. Apparatus in accordance with claim 6 also including:
a gain controlled peaking signal translator responsive to said cored peaking signal;
means for combining the output of said gain controlled peaking signal translator with luminance signals derived from said source to form a peaked luminance signal;
a frequency selective amplifier having an input responsive to said peaked luminance signal and exhibiting a pass band encompassing a high frequency region of the frequency band occupied by said luminance signals; and means, responsive to the amplitude of an output of said frequency selective amplifier for controlling the gain of said peaking signal translator.
a gain controlled peaking signal translator responsive to said cored peaking signal;
means for combining the output of said gain controlled peaking signal translator with luminance signals derived from said source to form a peaked luminance signal;
a frequency selective amplifier having an input responsive to said peaked luminance signal and exhibiting a pass band encompassing a high frequency region of the frequency band occupied by said luminance signals; and means, responsive to the amplitude of an output of said frequency selective amplifier for controlling the gain of said peaking signal translator.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US36386882A | 1982-03-31 | 1982-03-31 | |
| US363,868 | 1982-03-31 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1195767A true CA1195767A (en) | 1985-10-22 |
Family
ID=23432068
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000423032A Expired CA1195767A (en) | 1982-03-31 | 1983-03-07 | Adjustable coring circuit |
Country Status (2)
| Country | Link |
|---|---|
| JP (1) | JPS58182383A (en) |
| CA (1) | CA1195767A (en) |
Family Cites Families (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPS6042668B2 (en) * | 1976-07-07 | 1985-09-24 | 松下電器産業株式会社 | Image quality adjustment device |
| JPS53113428A (en) * | 1977-03-15 | 1978-10-03 | Mitsubishi Electric Corp | Noise rejecting circuit |
| JPS55109077A (en) * | 1979-02-15 | 1980-08-21 | Sony Corp | Producing circuit of aperture correction signal |
-
1983
- 1983-03-07 CA CA000423032A patent/CA1195767A/en not_active Expired
- 1983-03-28 JP JP58053449A patent/JPS58182383A/en active Granted
Also Published As
| Publication number | Publication date |
|---|---|
| JPH0328875B2 (en) | 1991-04-22 |
| JPS58182383A (en) | 1983-10-25 |
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