SE427404B - DEVICE FOR CHANGING THE TIME BASE WITH A DIGITAL INFORMATION SIGNAL - Google Patents

Description

vsozssu-6 2 signal reproduction required in high resolution signal processing systems. By way of example, time-stable signal generation is desirable in all television signal processing systems and highly stable generation is necessary in systems used to produce television signals for general broadcasting.

Two techniques are used to correct unwanted time base errors of signals reproduced from a recording medium, namely electromechanical and electronic. Electromechanical techniques are used to correct gross time base errors and achieve this correction by synchronizing the work of the signal recording and reproducing equipment. Electronic techniques are used to correct minor, residual time base errors, which have not been corrected by the electromechanical devices, and achieve this correction by time shifting of the signal after its reproduction. It is the electronic technique for time base error correction to which the present invention relates.

Heretofore, electronic systems for changing a signal time base have utilized adjustable time delay devices, which are inserted into the signal path to correct time base errors. In these systems, the time base error is measured and the degree of time delay introduced into the signal path is adjusted to compensate and thereby correct the measured time base error. A particular type of system that enjoys general use has a voltage variable delay line in which concentrated, constant inductances and voltage variable capacitive diodes are connected to a delay line configuration. A voltage, * corresponding to the measured time base error, is applied to the variable diodes to determine the necessary delay for correcting the time base error. A description of a signal time base change system, which is of the voltage variable delay line type, is given in U.S. Pat. No. 3,202,769.

In another type of electronic signal time base change system, a number of fixed delay lines or a single delay line, along which a series of sockets are distributed, are arranged in combination with electronic switches. Time base error is corrected by acting on the switches in accordance with the measured error to selectively introduce the necessary corrective delay in the signal path. A fixed delay signal type signal time change system is described in U.S. Pat. No. 3,763,317 and a signal time base change system having a socket delayed type is described in U.S. Pat. No. 3,780,383,116.

Recently, digital delay devices, such as clocked storage registers, have been used in systems for correcting time base errors of analog signals. The analog signal, which is corrected, digitized, corrected and regenerated in the digital systems. The correction is performed by inputting or writing the digitized signal in an adjustable storage register at a fixed rate, which is determined by the frequency of a reference clock signal. The storage register is affected to correct time base errors by reading the signal from the register at an adjusted faster or slower speed depending on the time base error. This constant write speed and variable read speed technology cannot handle large, discontinuous or incremental time base changes of the signal. In magnetic tape recording devices, such incremental time base changes are usually caused by anomalies in the operation of the devices and most commonly when switching between magnetic transducer heads.

In signal time base change systems, especially those arranged to eliminate time base errors and achieve a high degree of signal time base stability, it has been the practice to cascade rough time base correction devices and fine time base correction devices. Voltage variable delay line systems have been used to achieve the desired fine time base correction, while switched delay line systems have been used to achieve the coarser time base corrections. Because all such delay line systems are analog devices, they are prone to operate and have other disadvantages of analog devices. Incremental time base changes, which occur as a result of anomalies in the work of tape recorders, often cause errors or costly interruptions in the execution of the signal processing operations due to the inability of these time base error correcting devices to respond to incremental changes. If a large time base error range needs to be corrected, large and complicated correction systems are also necessary.

Significant benefits can therefore be gained by utilizing a technology for implementing signal time base compensation, which technology has the ability to affect all time base changes, including incremental ones, without error. Additional advantages will be experienced in performing such signal time base compensation by first changing the signal time base by a fraction of a known increment, required to carry the signal within a whole number of known increments of the desired time base reference, and by then change the time base of the signal by such an integer number of known increments that the signal is adjusted to the desired time base.

A feature of the present invention is the use of digital techniques to change the signal time base, which enable the use of digital circuits which are considerably less expensive to design and maintain than analog circuits. Another feature of the present invention is that the time base compensation can be performed without the need for an analogous measurement of the degree of desired compensation, thereby avoiding all the disadvantages characteristic of analog measuring couplings.

A device for changing the time base of a digital information signal with a first time base synchronizing component, which determines the interval of the digital information signal, and a second time base synchronizing component having a higher nominal frequency than the first time base synchronizing component, is characterized in accordance with the invention. addressed memory locations for receiving and storing digital information, means for providing the storage of successive portions of the digital information signal during each interval in different, addressed memory locations in the memory at times determined by a clock signal, means for providing recovery of the stored parts of the information signal from addressed memory locations at times determined by the clock signal, and means for responding to the first time base synchronization component of the information signal and a time base reference signal for each interval of the digit The information signal adjusts the time between the storage of each part of the digital information signal in an address and the recovery of that part from that address in accordance with the time difference between the first time base synchronization component and the reference signal in integer periods of the second time base synchronization component.

In summary, the present invention enables a change or correction of an information signal time base by using inexpensive digital circuits and without the need for analog measurement couplings.

The invention also enables the use of a single clock signal for performing the storage and retrieval of digital information in a storage device, which is used for time base change or correction of the digital information signal. The invention further enables change or correction of an information signal time base with large 5 vsossza-6 time increments without the introduction of discontinuities in the information signal. Finally, the inventive processing for time base change or correction does not degrade the quality of the information signal as analog processing does.

The invention will be described in more detail in the following with reference to the accompanying drawings. Fig. 1 is a block diagram of a digital time base compensator according to the present invention, which time base compensator is adapted for a color television signal. Fig. 2 is a detailed block diagram illustrating the construction of the recyclable digital memory in the compensator of Fig. 1. Figs. 3A and 3B are timing diagrams illustrating the method of signal-time base compensation according to the present invention in eliminating time base errors from color television signals. Fig. 4 illustrates in block form circuits which allow the time base compensator in Fig. 1 to correct larger errors than a period of the color synchronizing pulse of the signal. Fig. 5 illustrates in block form circuits which allow the embodiments of Figs. 1 and 4 of the time base compensator to operate when the incoming signal is a monochrome television signal.

The signal time base compensator 110 shown in Fig. 1 according to the present invention is arranged to eliminate time base errors present in a color television information signal reproduced from such a video recording apparatus (not shown) as a magnetic disk recording apparatus. It will be appreciated, however, that the principles of the present invention are equally applicable to performing other signal time base compensations, such as correcting time base errors in other time variable information signals, eliminating differences in signal relative time bases, and intentionally changing signal time base. With particular reference to Fig. 1, the uncorrected color television signal reproduced by the disc recording apparatus is fed to the input of an encoding analog-to-digital converter III, which is arranged to provide at its output 111 an encoded signal in the form of a pulse code modulated representation of the television signal. This representation signal is further processed to finally be coupled error-free to a decoding digital-to-analog converter 113, which decodes the digitized signal and at an output 114 reproduces the television signal in analog form. Due to the fact that the synchronization components included in the television signal output from the digital-to-analog converter 113 are usually malformed and contain unwanted transients as a result of their passage through the compensator 110, the television signal is coupled to an output processor 116 of the type used in video recording. Such processors 116 are arranged to peel off the synchronizing component signals from the incoming television signal and to introduce new, properly shaped and timed synchronizing components into the signal to form the desired composite television signal at its output 117.

In the compensator 110 according to the invention, the coding analog-to-digital converter 111 provides a multi-bit representation of the incoming signal at the output 111 each time the converter 111 is clocked by a clock signal applied via a line 111, as shown. The converter III is clocked to sample the instantaneous analog amplitude of the incoming television signal, so that a sequence of binary words is produced at its output 111, each word consisting of a number of binary bits, which bits together represent a particular amplitude level. in a binary format. This analog-to-digital conversion operation can generally be referred to as pulse code modulation of the incoming signal. The opposite of this operation is performed by the decoding digital-to-analog converter 13. The decoding converter 113 receives the binary, encoded words on an input, which is connected to a line 119, and in response to a sequence of reference clock signals, received over lines 121 and 122, leaves a re-imagined or decoded analog television signal to an output processor ll6, which forwards the corrected television signal to output ll7. In accordance with the present invention, the time base error compensation is achieved by deriving a clock signal from a time base component included in the television signal, so that the clock time of the derived clock signal is coherent with the time base component.

The derived clock signal is used to clock control the analog-to-digital converter III to sample the uncorrected television signal and perform the coding of the television signal into the digital binary word representations. After the coding, the digitized television signal is stored and decoded in the digital-to-analog converter 133 by means of a clock signal at a clock time which is coherent with a reference time base signal, such as a reference color subcarrier. As a result of this storage and decoding, the decoded television signal is brought into phase with the reference color subcarrier.

In the case of a color television signal, precise time base corrections can be achieved by deriving the information signal related clock signal from the color sync pulse time base component located in the rear of each horizontal line quenching interval by remotely accessing the line. binary word representations for one or more periods of the color sync pulse of the signal, available at the output ll2 of the analog-to-digital converter lll. The memory 123 forms a digital memory for a plurality of binary words, which corresponds to the amplitude levels of the color sync pulse of the signal at the sampling times. By storing the binary words available during the sampling of the color sync pulse of the signal, sufficient information is stored in the memory 123 to repetitively regenerate an entire period of the color sync pulse so that a conti-. current signal, which is identical to the color sync pulse of the uncorrected television signal, may develop and be beyond the duration of the color sync pulse of the signal. The derived clock signal is obtained by further processing the continuously regenerated color sync pulse signal and is used to digitize the remainder of the horizontal line of the television signal from which it was regenerated.

To ensure that the continuous signal, i.e. the derived clock signal, which is regenerated from the color sync pulse sample, which is stored in the recyclable memory 123, remains in phase with the color sync pulse, i.e. the uncorrected television signal, the analog-to-digital conversion of the analog-digital converter is clocked during sampling. and the resulting samples are stored by a clock signal at a clock time which is coherent with the reference clock signal. Thus, the analog-to-digital converter III must be clocked by two clock control signals via line 118. The first clock control takes place during a sampling and storage mode, which preferably lasts for several periods of the color sync pulse time base component. In this initial mode, the clock input (K) of the analog-to-digital converter 11 receives via a line 11 a clock control signal which is locked in phase with the reference clock signal, the AnalQq digital converter 11 is clocked by the second, derived clock control signal, received via line 118, a subsequent recirculation mode, which lasts for the remainder of the horizontal line interval after the initial clock control. For these two modes of operation, a switching means 124 is provided with a switching device 126 in a first state or sampling and storage state, in which state the device connects the line 118 to the clock output line 122 from an X3 reference clock source 128. The switching device? 803831 + -6 8 126 is operable to a second state or recirculation state, in which it connects line 118 to a line 127 from a digital memory circuit 129 to provide the derived clock signal. In the recirculation mode, the switching device 126 connects the clock input (K) of the analog-to-digital converter 11 to an X3 signal clock 131, which leaves a clock output signal for the memory circuit 129. The X3 signal clock 131 responds via a bandpass filter 132 for an output signal from a digital-to-analog converter 133. the analog converter 133 converts or reshapes the binary word representations of the signal color sync pulse, recirculated in the recirculable memory 123, into an analog form. Accordingly, the signal available from the digital-to-analog converter 133 appears as a continuous, unfiltered copy of the input signal time base component, which in this preferred embodiment is a sinusoidal color sync pulse in a television signal. The bandpass filter 132 is set to have a center frequency equal to that of the color sync pulse in the signal being corrected, which in the case of a standardized NTSC color television signal is a frequency of 3.58 MHz. In its place between the output of the digital-to-analog converter 133 and an input of the X3 signal clock 131, the filter 132 has been found to provide an advantageous reset of the color sync pulse frequency after the various conversion and digital storage manipulations. If a number of color signal sync pulse cycles or periods are sampled and stored in the memory 123 to regenerate the derived clock signal, the filter 132 will equalize each noise included in the recycled color signal sync pulse over the number of stored periods, thereby improving the time accuracy of the derived clock signal.

As indicated above, the switching device 126 in the switching means 124 is normally in its degenerate second or recirculated state, the X3 signal clock 131 being connected to the clock input (K) of the analog-to-digital converter III for controlling the sampling and timing of the coding of the uncorrected television signal. In order to effect the switching means 126 to its first state or its sampling and storage state, the switching means 124 includes circuits for detecting the occurrence of the color sync pulse time base component thereon in the television. affect the device 126 accordingly. In particular, a sync separator 134 is provided to detect at the input of the compensator 110 the occurrence of each horizontal sync pulse (SIG H) which occurs during the blanking interval in each horizontal line of the television signal.

The output of the separator is connected to the input of a switch control pulse generator 136. Upon detection of the leading edge of the horizontal sync pulse, the separator 134 leaves an instruction to the pulse generator 136. After an interval of about 6 us, the pulse generator 135 leaves a pulse lasting about 2.0 us. to transfer the switch 126 to its sampling and storage state. Thus, in response to the occurrence of a horizontal sync pulse at the input of the analog-to-digital converter III, the separator 134 and the pulse generator 136 cause the switching device 126 to supply the coding X3 reference clock signal to the clock input (K) of the converter III, which in response digitizes selected number of periods of the signal color sync pulse. The timing of the operations of the separator 134 and the pulse generator 136, as specified herein, is provided for NTSC television signals so that the switch 126 is transferred to its sampling and storage state during the middle interval of the color sync pulse interval. It is desirable to cause the sampling and storage of digital representations of the color sync pulse of the signal to occur in the middle of the color sync pulse interval, as this interval is the most accurate and reliable in representing the color sync pulse frequency. In addition, the derivation of the information signal-related clock signal is less susceptible to errors, which can be introduced by small changes in the position of the color sync pulse in the rear part of the horizontal blanking interval.

To condition the recirculable memory 123 for storing five periods of digital color sync pulse representations, a sync pulse detector 137 is connected to the input of the compensator 110. Upon the appearance of the color sync pulse in the incoming television signal, the sync pulse detector 137 leaves an instruction on a line 138 which extends to the write enable (SK) write enable input (SK) input. This instruction causes the memory 123 to write the binary multi-bit word that appears on the output ll2 of the analog-to-digital converter lll. The actual write or store operation takes place at each reference clock time, which is determined by a vaozsza-s _ l., Clock input to the memory 123 from the X3 reference clock 128. The continued operation of the recyclable memory 123 can best be described with reference to both Fig. 1 and Fig. 2.

Referring to Fig. 2, the memory 123 includes a direct access memory 139 with conventional write and address control inputs, denoted by the symbols (S) and Q). A binary word input is coupled to receive the binary multi-bit word at the output 112 of the analog-to-digital converter 111. A binary word output is provided for outputting the recirculated digital signals to the line 140. An address generator 141 responds to a source of X3 reference clock signals over line 122 and provides via a connection 142 address signals for write and read access to the memory 139 in accordance with the generated address signals. The memory 123 includes a write clock generator 143 which responds to the instruction received from the sync pulse detector 137 via line 138. The instruction sets the write clock generator 143 to output write enable signals via line 144 to the write enable input (S) of the direct access memory 139 each time an X3 reference clock signal is received from line 122.

As long as the write enable signals are received by the direct access memory 139, the binary words output by the analog-to-digital converter 111 will be written for storage in the memory 139. The memory 123 also includes a counter 145, which responds to the instruction received at its reset input (Å). , connected to line 138, from the sync pulse detector 137. The instruction resets the numerator 145 to count the addresses left by the address generator 141. The counter 145 is also reset by an internally generated instruction, as will be described later. Each time the counter 145 is reset, it leaves a reset instruction via a line 146. The first reset instruction issued after the instruction provided by the sync pulse detector 137 on the line 138 is switched to deactivate the previously activated write clock generator 143 by resetting it until the next instruction is given by the sync pulse detector 137.

In this way, the direct access memory 139 is prevented from receiving additional binary word representations_of the television signal after fifteen samples of the color sync pulse have been received. The counter 145 also serves to recycle the address generator 141. Each time the address generator 141 outputs an address signal, the activated counter 145 is clocked by an X3 reference clock signal received from line 122 to examine via a line 147 the address given by address generator 141 and connected to its data input (D). When the counter l1 7803834-6 145 detects the output of the last of fifteen address signals output by the address generator 141, it leaves a reset instruction to the address generator via line 146. The counter also uses this reset instruction internally to reset itself and re-examine the address generator 141. address signals.

In this way, the address generator 141 is caused to continuously review the fifteen addresses that identify the locations in the direct access memory 139 in which the fifteen binary multi-bit words, which represent the five sampled periods of the signal color sync pulse, are stored.

A further explanation of the operation of the recyclable memory l23 will be provided herein along with a description of an actual operation sequence of the compensator 110.

When selecting the rate at which the incoming information signal must be sampled, the clocking or sampling frequency must be at least twice as high as the maximum signal frequency that the system is to emit without significant deterioration. In addition, the rate of caching and storage capacity of the direct access memory 139 must be chosen so that the number of digitized samples stored in the direct access memory 139 is equivalent to an integer number of whole periods of its time base component, ie equal to the product of the number of samples per period for the time base component. . With the clock rate and the storage capacity thus selected, the memory 139 carries a whole number of digital representations of entire periods of the signal control component of the signal, which upon recirculation results in the generation of a continuous clock signal during the recirculation mode. In the case of a color television signal, both the storage capacity and the sampling rate criteria are advantageously met by selecting the frequency of the coding clock signal three times higher than the color sync pulse frequency and by storing fifteen samples of the color sync pulse. Accordingly, in the exemplary embodiment, the X3 signal clock 131 includes a frequency multiplier for multiplying by a factor of 3 the continuously regenerated color sync pulse signal developed by the memory 13, digital-analog converter 1111 and the band-pulse 112. and the coding clock signal used in the storage mode must be nominally equal to the determined coding rate, although the phase may differ from the derived clock signal in accordance with the time hash error of the signal being compensated.

In the embodiment according to Fig. 3, the basic reference time signal is the reference color subcarrier available from the studio reference source for synchronous processing. 12 Reference color subcarrier This reference color subcarrier is fed to a reference signal processor which is a component 148. and similar fixed delays and the development of the necessary phase change_ of the reference signal for European color systems, such as the PAL system.

The output of the processor 148 leaves the basic reference time base signal, relative to which the compensator 110 operates to compensate for the incoming television signal. Due to the need for an X3 reference clock signal, the frequency of the basic reference time base signal is multiplied by a factor of 3 by a frequency multiplier included in the X3 reference clock source or generator 128. Since an X1 reference clock signal is required by the most preferred form of the compensator 110, an X1 reference clock generator 149 is coupled to receive the reference time base signal from the processor 148 and outputs via line 121 the required X1 reference clock signal. and decoding clock rates, the analog-to-digital converter III is arranged to develop a separate, binary word at each of the three clock times which occur during the interval equal to a period of the color sync pulse. In this case, the analog-to-digital converter III is designed to provide a word of 8 bits at each clock time, which 8 bits provide an amplitude level capacitance of 0-256 for the digital representation of the incoming television signal. The recyclable digital memory 123 therefore has a capacity of 15 words, each word again consisting of 8 bits. Since there are three sampling points for each color sync pulse period, the memory 123 direct access memory 139 is arranged to store five whole periods of the digitally represented color sync pulse. Although the pulse generator 136 in operation outputs the pulse with a length of 2 μs in response to the detection of the horizontal sync pulse, the memory 139 is instructed by the write clock generator 143 (at the occurrence of the sync pulse) to write or store the binary words appearing on the analog-to-analog converter 112 output 112. the time of each X3 reference clock signal received on line 122. Referring to Fig. 2, this operation in particular causes the address generator 141 to access a new word memory position in the memory 139 in response to each of the X3 dual clock pulses, each again accessible word memory position receiving the instantaneous bit states of the binary word2. The 2 us long pulse emitted by the pulse generator 136 temporarily adjusts the switching device 126 in its sampling and storage state, whereby the X3 reference clock signal is switched for clocking the analog-to-digital converter III. The storage operation is completed after the five periods of the digitized color sync pulse have been stored by the counter 145 detecting via the line 147 the fifteenth address generated by the address generator 141 after the output of the 2 μs long pulse and outputting the reset instruction to the write clock generator 143. Reset instruction disables the write clock generator, thereby removing the write enable signals from the direct access memory 139. ' Upon completion of the sampling and storage mode, the address generator 141 continues to provide access to the memory 139 in response to the X3 reference clock signal via line 122, successively repeating the same fifteen word locations to which access was gained during the write operation. This causes the stored words of 8 bits to be read out successively via the output line 140 to the digital-to-analog converter 133. The memory 139 is permanently arranged in an active read mode, so that the stored binary words are continuously read out via the line 140. The read function is active during the storage of new digital information, received from the analog-to-digital converter III, by the actuation of a bypass switch 151. The switch 141 has two inputs and one output. One input of the switch 151 is connected by a line 153 to the output of the access memory 139 and its second input is connected via a bypass line 154 to the line 112 to the input of the memory 123. Although set to provide write enable signals during the sampling and storage mode, the write clock generator 143 conditions the bypass switch 151 to connect the lines 112 and 140, thereby passing the binary words stored in the memory 139 directly to the output. At the end of the sampling and storage mode, the write clock generator 143 is deactivated, the switch 151 being transferred to a state for connecting the output line 153 of the memory 139 to the line 140. The switch 151 remains in this state throughout the recirculation mode, bringing the stored color sync pulse words to be connected to the digita1 analog converter 133 for deriving the information signal related clock signal. The provision of the pre-switch 151 makes it possible to prepare the X3 clock signal circuits for the generation of the derived X3 clock signal.

During the recycle mode, the address generator 141 and the counter 145 work together to produce the repetitive generation of the same address sequence. As a result, the binary words stored in the memory 139 are repeatedly read in this order for the remaining time of the horizontal line interval after the color sync pulse.

Figures 3A and 3B illustrate the manner in which the derived clock signal is generated to be in phase with the time base component of the information signal from which it is derived. Fig. 3A illustrates the state that would prevail if the incoming color television signal were faultless. During the sampling and storage interval, the X3 reference clock provides the sampling of the color sync pulse of the signal in the analog-to-digital converter III and the storage of the sample values in the recyclable memory 123. Because the incoming television signal is error-free, the first sample of each period of the color sync pulse of the signal at the beginning of the color sync pulse period. When the fifteen words stored in the memory 123 are recirculated, the output signal of the filter 132 will be in phase with the color sync pulse included in the incoming television signal. If a time base error is present in the incoming television signal, as illustrated in Fig. 3B, the sample values represented by the binary words obtained from the analog-to-digital converter III will be different. This difference exists due to the time base difference between the reference time base signal and the incoming television signal, hence the different sample points during the color sync pulse period. When the fifteen words stored in the memory 123 are recycled, the regenerated color sync pulse output signal from the filter 132 will be in phase with the color sync pulse included in the incoming television signal. The clock signal obtained from the output of the filter will thus always be in phase with the time base component included in the television signal, regardless of the time base changes or errors that may occur in it.

Although in this case a direct access memory, an address generator and counter means have been used for the recyclable memory 123, it will be appreciated that other digital storage circuits may be used instead.

As an example, a recirculating shift register can provide the memory 123 function, as will be appreciated by those skilled in the art.

To facilitate the avoidance of errors in the time shift or time conversion of the digital representations of the television output signal from the analog-to-digital converter III during the recirculation mode, a time buffer device 156 is used, which at its input has a converter 157 for converting a serial word into three parallel words and at its output a complementary converter l58 for converting three parallel words into a serial word. The converters 157 and 158 are shown in Fig. 4. The sequence of individual binary words produced at the output ll2 is passed to series-parallel converter needles. This converter 157 receives each of the successive binary words at a clock rate three times that of the recirculated signal color sync pulse, by applying the clock pulses from the X3 clock source available on line 118 to the clock input (K) of this converter, as indicated. The converter 157 is designed to store three of the binary words generated in series at the output 112 and is of the type in which each new word added to the converter replaces the last word from the converter, which always contains three whole binary words. The serial input information is transmitted in parallel to the converter 158 via a clock isolator 163 (see Fig. 4), which is included in the time buffer device 156.

During each line interval of the incoming television signal, the transmission time to the clock isolator 163 occurs at the clock time determined by clock pulses generated by an IX signal clock 159 (see Fig. 1). The 1X signal clock is coupled to the output of the bandpass filter 132 to generate a clock pulse signal at the recirculated color sync pulse frequency, which is the frequency of the color sync pulse as it appears at the beginning of the line interval.

In particular, the IX signal clock 159 is achieved by limiting the filter output signal and using a positive leading edge of the square waveform thereby generated to produce the clock pulses. Each positive-going leading edge of the limited, regenerated color sync pulse identifies the beginning of a period of the color sync pulse. The 1X signal clock 159 is connected to the time buffer device 156 via line 161. In this way, in response to each applied clock pulse, the clock isolator 163 receives the entire contents of the converter 157, which as discussed above has three integer binary words generated by the analog-to-digital converter. lll at the output 112. The three words, received in parallel format by the clock isolator 163, further correspond to the three words developed during a period of the regenerated color sync pulse.

The output signal from the converter 157 is a 24-bit word, which is connected to the input of the clock isolator 163. The isolator has the ability to read and write the 24-bit words at the same time. Because the isolator 163 can read and write simultaneously, the clocking operations can be performed on its input and output sides with respect to different, jckv-coherent clock signals, whereby the time buffer charging causes- If- (nnnu-r: likfznm uvšj] iqhf-l- -n at l. tír1: '. 1¿) |: .l ~; j \ xl.x cI lm lixlzzuvxf-ííil ïil' V-ïll 'nalerna. For writing or storing the output signal of the converter 157, the clock signals generated by the signal clock 159 are switched by means of the converter 161 to a write address input (SA) and a write enable input (SK) to the insulator 163. This clock signal is in phase with the uncorrected the color sync pulse of the television signal. The stored 24-bit words associated with each period of the time base component are read or output from the isolator 163 in response to 1X reference clock signals provided by a reference clock generator 149 and connected to a read address input (LA) to the isolator 163 via a line 121.

By clocking the insulator 163 with two clock signals, the phase of the isolator output signal will be time-shifted or time-shifted and synchronized with the phase of the reference color subcarrier.

The converter 158 is complementary to the converter 157 in that it provides a transfer from parallel form to serial form of the digital word information received from the converter 157 via the clock isolator 163. The converter 158 thus converts the digital information into a serial word of 1 word, but in this case the serial words are clocked out of the converter l58 at a clock time determined by the 1X reference clock signal which is applied to the converter 158 via the line 121, as indicated in Fig. 4. These serial words are fed via the line ll9 to the input of the digital-to-analog converter l13 and then decoded under the control of the 3X reference clock signal on line 122. The digital-to-analog converter 113 regenerates the desired analog signal on the output 114 synchronized with the phase of the reference subcarrier.

In the manner described above, the digital compensator according to the present invention is arranged to synchronize an incoming information signal with a reference or standard time base signal.

It is observed that the time correction area in the present embodiment is a period corresponding to the entire period of the time base component.

More specifically, in the case of a color television signal, the correction range is a period of the color sync pulse frequency, which is l divided by 3.58 MHz or about 0.28 us. If the phase error of the incoming video signal is likely to exceed this range, as may occur when reproducing television signals from tape recorders, then the signal output at output 114 will be shifted to synchronize the phase of the color sync component with the reference color subcarrier. However, the horizontal synchronization of the television signal will be incorrectly bevelled relative to the horizontal reference sync signal. For some applications, such as in connection with disk recording equipment, the correction range provided by the present 17 Vaasan embodiment is about an entire period of the color sync pulse or 0.28 μs is sufficient without the aid of additional time base error compensating systems.

If the occurrence of larger time base errors is probable, a direct access memory 164 is inserted between the clock isolator 163 and the parallel series converter 158, as shown in Fig. 4. The memory 164 corrects the time base of the signal by increments equal to an integer of the color sync pulse. period. This is accomplished by writing the word of 24 bits into addresses in the memory 164, which addresses are determined by a write address generator 166. The memory 164 is activated at its activation input (SK) for writing the word of 24 bits and the generator 166 is clocked. of the IX reference clock signal on line 121. The contents of the memory 164 are read in accordance with the address provided by a read address generator 167. The read address provided by the generator 167 is determined by the relative times of occurrence of the horizontal sync pulse of the signal and reference. The relative occurrence times are determined by a counter, which serves as a horizontal sync comparator 168. The counter 168 starts counting in response to the horizontal reference sync pulse and is stopped by the occurrence of the horizontal sync pulse of the signal. The counter 168 counts at the rate of the color sync pulse. The output of the counter 168 is connected to the position input (S) of the read address generator 167 and changes by setting the output read address in accordance with the number in the counter 168 after the occurrence of the horizontal sync pulse of the signal.

The successive words of 24 bits are written in successive addresses in the memory 164. The capacity of the memory 164 can be adjusted as desired. For a correction of at least one horizontal line interval, i.e. approximately 63.5 us, the memory 164 is arranged to have a capacity of 256 words. Each word represents a time of a period of the color sync pulse, i.e. about 0.28 us. A capacity of 256 words will therefore give a storage time over 63.5 us. The read address generator 167 is set relative to the write address generator 166, so that, if the horizontal sync pulse of the signal and the horizontal sync pulse of the reference are in phase, identical addresses generated by the two generators will be separated in time equivalent to what is required to recycle approximately half of the memory capacity, the write address generation being before the read address generation. For a correction capacity on a horizontal line interval, the difference is approximately 32 us.

The above-described construction and mode of operation of the present invention relates to a system for correcting an information signal which has a repeatedly occurring time base synchronization component in the form of a sync pulse of alternating amplitude variation such as a color sync pulse. The present invention can also compensate for time base error information signals which lack or have time base components in a form other than an alternating amplitude time base signal. By way of example, a monochrome television signal may be corrected in accordance with the principles of the present invention by introducing an artificial sync pulse or pilot signal consisting of a sync pulse of varying amplitude variations into the television signal during the blanking interval.

In particular, such a sync pulse signal may be applied to the rear of each blanking interval which accompanies the horizontal line of a monochrome television signal, the horizontal sync pulse serving as the time base component, relative to which the introduced pilot signal is selected to have a predetermined phase ratio.

Referring to Fig. 5, a modification of the system of Fig. 1 to compensate for a monochrome television signal by introducing an artificial sync pulse signal consisting of a sync pulse of time base information of varying amplitude is illustrated. The sync pulse input is effected by means of a oscillating oscillator sync pulse generator 171 with an input controlled by the uncorrected, monochrome horizontal sync pulse provided by the sync separator 134. An output line 173 from the generator 17 for input into the monochrome television signal at a summing point 174 via a conductor 177 from a gate 176. Point 174 is achieved by means of a conventional signal summing circuit. By this arrangement, the generated artificial sync pulse signal is introduced into the monochrome television signal before the input of the incoming signal to the coding analog-to-digital converter III in this case. This arrangement only works in the absence of a color sync pulse occurring in the incoming signal. For this purpose, a connection is made from the output of the sync pulse detector 137 to the gate 176 for inactivating the gate, whenever a color sync pulse is detected in the incoming signal.

Apart from the fact that the sync pulse signal in the system according to Fig. 5 is generated and introduced artificially, this system for use with combined monochrome television signals reaches substantially the same manner as described in connection with the system according to Fig. 1, which system is used for color television signals. The artificial sync pulse generator 171 is designed to generate a sync pulse signal with the same frequency and phase ratio as a color sync pulse, so that the normal reference color subcarrier can be used as a reference time base signal in the monochrome circuit of Fig. 5. This is achieved. with the present invention in that the generator 171 receives from the sync separator 134 the horizontal sync pulse in each monochrome television line as it appears in the incoming television signal, and utilizes the leading edge of the horizontal sync pulse to trigger a phase controlled oscillation circuit designed to provide an oscillation frequency which is equal to that of the normal color sync pulse, which frequency in turn is nominally equal to the frequency of the reference color subcarrier. The phase of the sync pulse output signal generated by the oscillation generator 171 is controlled in accordance with the output of one with two dividing flip-flops 179, which has an input which is sensitive to the leading edge of the horizontal sync pulse developed by the sync separator 174. outputs 181 and 182, corresponding to the opposite sides of the flip-flop 179, through which signals are emitted, which are 1800 phase-shifted. The purpose of the two dividing flip-flop 179 is to drive the phase-controlled oscillator oscillator 171 so that it develops a 180 DEG phase change at each television line to bring the artificially generated sync pulse signal into conformity with the common phase change which occurs between sync rate in a standardized NTSC color television signal.

The rocker l79 consequently reacts for each horizontal sync pulse by changing state. In response to a first horizontal $ Y fl kPU1 $ f m0ttä9BH from separator 134, output l8l will switch from low to high level, while output 182 will simultaneously switch from high to low level. The next horizontal sync pulse will cause an opposite transition. The phase controlled oscillator 171 is designed to react only for output signal transitions from the outputs 181 and 182, which transitions take place from low to high level.

As each artificial color sync pulse occurs at output l73 after the horizontal sync pulse, the 2 μs long output pulse provided by pulse generator 136 affects gate L76 to cause it to assume its set state. A mono / color switch 181 is also set to disconnect the pulse from the pulse generator 136 to control the recirculating memory 233 instead of the ground sync detector 137.

Claims (5)

7803834-6 20 PATENT CLAIMS A device for changing the time base of a digital information signal with a first time base synchronizing component, which determines the interval of the digital information signal, and a second time base synchronizing component having a higher nominal frequency than the first time base synchronizing component, characterized by a direct digital access memory (164) having addressed memory locations for receiving and storing digital information, means (149, 166) for providing the storage of successive portions of the digital information signal during each interval in different, addressed memory locations in the memory (164) at times determined by a clock signal, means (149, 167) for effecting recovery of the stored portions of the information signal from addressed memory locations at times determined by the clock signal, and means (167, 168) for in response to the first time base synchronization component of the information signal and a time base reference for each interval of the digital information signal adjust the time between the storage of each part of the digital information signal in an address and the recovery of that part from that address according to the time difference between the first time base synchronization component and the reference signal in integer periods of the second time base synchronization component . Device according to claim 1, characterized in that the digital direct access memory (164) has a data storage address input (SA), a data recovery address input (LA) and input and output data connections, that the storage means (149, 166) comprise a write address generator (166) for generating in response to the clock signal a sequence of memory location identifying write address signals, which are coupled to the data storage address input (SA), the digital direct access memory being arranged to store the addressed memory information at the addressed memory location on the digital memory location. the data connection means, and that the recovery means (149, 167) comprises a read address generator (167) for generating in response to the clock signal a sequence of memory location identifying read address signals, which are connected to the read address input (LA), the digital direct access memory (164) being arranged that in response to each addition first read address signal on its output connection provide the digital information signal stored in the addressed memory location. vsozszß-6 21 3. Device according to claim 2, characterized in that the read address generator (167) is arranged to generate each read address signal in response to the reference signal at a time between the generations of successive write address signals. Device according to claim 2 or 3, characterized in that the storage and recovery time adjusting means are connected to set the read address generator (167) at the beginning of each of the successive intervals of the digital signal for â producing a first read address signal in the sequence selected in accordance with the time relationship between the information signal's first time base synchronization component and the reference signal. The apparatus of any of claims 2-4, wherein the information signal is a television signal, the first time base synchronizing component comprises periodically occurring line pulses determining intervals of the information signal, and the second time base synchronizing component is an amplitude varying synchronizing sequence. after each line pulse, characterized in that the storage and recovery time adjusting means (167, 168) comprises means (168) for comparing the time ratio between each line pulse and the time base reference signal to provide a signal representation of the time ratio in whole number of periods of the amplitude variances. the nominal frequency of the synchronizing signal, the read address generator (167) being arranged to, in response to the time ratio signal, produce the first read address signal in succession in accordance with the represented whole number of periods.