Composite-video-signal-text-adder

This circuit demonstrates a straightforward method for incorporating text information into a composite video signal that may be at an undefined DC level. It is essential that the text generator and the composite video source utilize the same synchronization signal. The input and output video signals share a common terminal. Capacitor C3 couples the video signal to the output of a rectifier circuit, which is constructed using a sub-video-speed operational amplifier. A higher-speed operational amplifier would clamp onto individual sync pulses instead of the average value of the video waveform, which is the intended function in this design. Resistor R1 acts as a pulldown resistor, while feedback resistor R10 ensures that test point TP6 remains at ground potential. The emitter follower transistor Q1 buffers the text signal, and resistor R5 functions as a gain control. A simple clamp circuit, implemented with transistor Q2, adequately regulates the amplitude since the text signal does not include gray-scale levels. Transistor Q3 is responsible for coupling the text signal into the operational amplifier clamp circuit.

The circuit operates by integrating a text overlay onto a composite video signal, which is essential for applications such as broadcasting or video production where additional information needs to be displayed alongside the video content. The synchronization between the text generator and the video source is critical to ensure that the text appears at the correct time within the video frame.

The use of C3 for coupling is vital in maintaining the integrity of the video signal while allowing the necessary DC offset for the text information to be superimposed without distortion. The rectifier circuit, based on a sub-video-speed operational amplifier, is designed to handle the lower frequencies associated with the sync pulses and video signals, ensuring that the clamping action does not interfere with the overall video quality.

R1 and R10 work in tandem to stabilize the voltage levels at critical test points, preventing any unwanted fluctuations that could lead to signal degradation. The emitter follower configuration of Q1 ensures that the buffered text signal maintains a high input impedance while providing low output impedance, which is crucial for interfacing with subsequent stages of the circuit.

The gain control provided by R5 allows for fine-tuning of the text signal’s amplitude, ensuring that it is appropriately balanced with the video signal. The clamp circuit, consisting of Q2, is specifically designed to handle the digital nature of the text signal, which does not require the complexity of gray-scale modulation. This simplicity allows for effective amplitude regulation without introducing additional noise or artifacts.

Finally, Q3 plays a pivotal role in coupling the text signal into the operational amplifier clamp circuit, ensuring that the text is integrated seamlessly into the composite video output. This design emphasizes the importance of component selection and configuration in achieving a reliable and high-quality video signal with overlaid text information.This circuit shows a simple way to add text information to a composite-video signal that might be floating at some indeterminate de level. The text generator and composite-video source must have the same sync signal. The video-input and -output signals share the same terminal. C3 couples the video signal to the output of a rectifier circuit that is based on a subvideo-speed op amp.

A faster op amp would clamp on individual sync pulses rather than on the video waveform"s average value, as is desired. Rll serves as a pulldown resistor and feedback resistor RlO ensures that TP6 remains at ground level. Emitter follower Ql buffers the text signal, and R5 serves as a gain control. A simple clamp circuit, Q2, is sufficient for regulating amplitude, because the text signal contains no gray-scale levels.

Q3 couples the text signal into the op-amp clamp circuit. 🔗 External reference