NL8901464A - MULTI-STANDARD VECTOR SCOPE. - Google Patents

Description

Mu.lt ± ~ standard ^ vectorscope

The present invention relates to a multi-standard vector scope for composite video signals.

In particular, the present invention is intended to work with standard PAL and NTSC video signals.

. The PAL ("Phase Alternation Line") standard refers to a color television system in which the V component of a subcarrier derived from a color burst is phase inverted in successive lines, in order to minimize hue errors that may occur with color transmission.

The NTSC ("National Television System Committee") standard is a standard that was named after an industrial research group that developed American color television specifications. The NTSC standard now describes the American system of color television broadcasting.

There are three PAL and one NTCS standards with different subcarrier frequencies. Prior art requires two or more different devices to view PAL and NTSC color information, each of which includes a separate oscillator. In the past, it has not been practical to combine the various devices due to potential crosstalk of the oscillators and the lack of a stable DC-controlled phase shifter and demodulator that are not frequency sensitive.

It is an object of the present invention to provide a multi-standard vectorscope for composite video signals that provides the ability to view both PAL and NTSC color information with different color carrier wave frequencies.

Briefly, the muiti standard vectorscope includes demodulators for receiving first and second video signals, each of which represents different standard video color information, such as the NTSC and PAL color information.

The vector scope also includes switchable oscillating means connected to the demodulating means for generating first and second oscillator signals corresponding to the first and second video color information signals, respectively.

The vector scope further includes controllers for switching between the first and second oscillator signals, depending on whether the demodulators receive the first or the second video signals. The demodulators demodulate the first or second video signals with the respective first or second oscillator signals in response to the respective pair of first and second signals, also depending on which of the first or second video signals are received by the demodulators.

Other objects, features and advantages of the present invention will become apparent from the following detailed description referring to the drawing, in which Figure 1 shows a block diagram of the multi-standard vector scope of the present invention; FIG. 2 is a diagram of a switchable crystal-controlled oscillator used in the present invention of FIG. 1; Fig. 3A shows a block diagram of a DC-controllable variable phase shifter; Fig. 3B shows diagrams of the types of control voltages used by the circuit of Fig. 3A; and FIG. 4 is a diagram of a variable DC control voltage generator used by the circuit of FIG. 3.

The present invention allows for a multi-standard vectorscope for composite video signals using the following techniques (in a preferred embodiment, a dual standard vectorscope). The present invention includes separate oscillators for each of the video standards and means to operate only one oscillator at a time, eliminating crosstalk from one to the other.

The present invention also includes a DC-controlled phase shift circuit independent of the subcarrier frequencies of the video standards. Therefore, it can be adapted to any system or a switchable system that uses any of the NTSC or PAL standards.

The present invention also allows input signals, either synchronous or non-synchronous, or delayed due to delays, to be displayed as if they were perfectly on time.

Referring to Fig. 1, a block diagram of a multi-standard vector scope 10 of the present invention is shown. Input signals 12 are received through a band pass filter (BPF) 14 to signal demodulators 16.

The outputs of the signal demodulators 16 are suitable for a conventional X-Y display monitor.

The signal demodulators 16 also receive a 90 ° delay signal from a delay circuit 18 and a subcarrier signal from a voltage controlled phase shift circuit 20.

A microprocessor system 30 provides suitable control by A / D circuits 32 and D / A circuits 34. The multi-standard vector scope 10 of Figure 1 includes a switchable oscillator 24 connected to a reference video signal 40 (corresponding to the PAL or NTSC standard) received through a bandpass filter 42 and a phase lock loop (PLL) circuit 44. Appropriate timing signals are applied to the PLL 44 through a timing circuit 46.

The switchable oscillator circuit 24 provides as an output on line 23 appropriate "oscillator signals depending on the NTSC or PAL type of color information to be used. In a preferred embodiment, the switchable oscillator 24 generates four times the subcarrier frequency for each standard, and outputs thereof divided down by sub-chain 22.

The output of sub-circuit 22 is input for a voltage-controlled phase shifter 20 and also for PLL circuit 44.

The multi-standard vector scope of Figure 1 provides the following functions: 1. Subcarrier-related frequency switching to follow the input video standard.

2. A DC controlled phase shift network, which is non-frequency sensitive, to adapt the different video standards together with a pre-adjustable phase for each standard.

3. A switchable, or non-frequency sensitive, delay circuit for the 90 ° phase shifter.

4. A timing chain to display the line and field speeds for each standard.

The present invention implements the aforementioned functional aspects to operate between two or more different television standards.

Referring to FIG. 2, the switchable crystal controlled oscillators which form part of the switchable oscillator 24 of FIG. 1. In FIG. 2, the crystal controlled oscillators 50, 52 provide first and second oscillator signals, respectively, for each standard four times the subcarrier frequency. Each oscillator 50, 52, each of which operates in a linear mode, is connected to an ECL device 54. The outputs of the oscillators 50, 52 are connected to each other at 56. By logic controlling the input of each oscillator 50, 52, only one oscillator will operate at a time, thus generating the appropriate oscillator signal at 58. This technique eliminates crosstalk between oscillators 50, 52 since only one is operating at a time, and provides stability to one oscillator controlled over the full range between the subcarrier frequencies.

Figures 3A and 3B illustrate the operation of the controlled variable phase shift circuit 20 of Figure 1, which is independent of the subcarrier frequency of each standard. A technique of the present invention uses a 4 times subcarrier frequency oscillator in which the frequency is divided by four by a frequency dividing circuit 22 as shown in FIG.

It is important to assume a 4 times subcarrier frequency, so that the frequency sub-circuit provides an in-phase and a 90 ° phase shifted subcarrier output signal which is independent of the incoming frequency. The respective latches output signals 60, 62 of FIG. 3A are inputs to modulators 64, 66, the other inputs of which are controlled by variable DC voltages.

The outputs of the two modulators 64, 66 are added and shaped by filter circuit 68, which retains the subcarrier frequency, but the phase is controlled by the variable DC voltages. The subcarrier is then buffered in buffer 70 and supplied to a limiting circuit 72.

The variable DC control voltages shown in FIG. 3B may be in the form of a DC voltage, a ramp voltage, a triangular voltage, or any continuous function that may be generated by any standard means. Fig. 3B shows the phase control voltage as a ramp voltage that simulates all allowed phase control input voltages and corresponding output voltages for controlling the variable phase shift device through a 360 ° phase shift.

Fig. 4 depicts a variable DC control voltage generator for generating the variable DC control voltages.

The phase control voltage for the variable DC phase control voltage generator is either set internally, controlled by an operator via a control panel, or controlled by a digital-to-analog converter (DAC) 34 controlled by the microprocessor 30 of FIG. 1.

An operator may instruct the microprocessor 30 to read the control panel phase control through an analog-to-digital converter (ADC) 32 of FIG. 1, and store that information in its permanent memory for later use.

The input video signals can then be displayed and controlled by the stored information synchronously so that the resulting output display appears to have both signals of the same phase. This allows viewing of signals with different delays by pre-setting the displayed phase to compensate for internal or external delays. Switching between different DC control voltages allows the display of untempered input signals as if they were tempered input signals. The demodulator 90 ° delay circuit 18 is, in one embodiment, provided by a switching capacitor network that serves as a low-pass delay filter. The timing chains can be implemented using known techniques.

In the phase shifter 20 of FIG. 1, an analog multiplier can be used as a modulator. The variable DC control voltage generator can be provided by two DACs under the control of the microprocessor, with which all continuous functions and repetitive time-variable voltage forms can be synthesized. This technique will also establish a monotone relationship between the phase shift and the control voltage.

Claims (6)

A multi-standard vector scope, comprising: modulator means for receiving input video signals; switchable oscillator means connected to the demodulator means for generating at least first and second oscillator signals, which oscillator means is connected to receive first and second standard color information signals corresponding to said first and second oscillator signals, respectively; controllers for switching between said first and second oscillator signals depending on whether the oscillator members receive the first or the second standard signals; and wherein the demodulator means demodulate the input video signals in response to said first or second oscillator signals. The vector scope of claim 1, characterized by phase-shifting network means to adjust the first and second standard signals. Vector scope according to claim 2, characterized by a DC-controlled phase shifter which is not frequency sensitive and which allows a 360 ° phase shift of the display of any video standard. The vector scope of claim 3, characterized by dividing means for dividing said first or second oscillator signals to a subcarrier frequency corresponding to said first or second standard signals, respectively. Vector scope according to claim 4, characterized by means for applying a variable DC control signal to the phase shifters. Vector scope as claimed in claim 5, characterized by means for switching between different DC control voltages to enable display of untamped input signals as if they were tamped input signals.