Light-controlled-lamp-switch
A school drama required lamps that automatically turned on and off in sync with the spotlights. The lamp switching system needed to be wireless, durable, reliable, simple, and cost-effective. With the stage and spotlights turned off, minimal light reaches the CdS photocell, resulting in its internal resistance being several megohms. This high resistance keeps the gate of transistor Q1 at nearly zero volts, thus keeping it off. When a spotlight or stage light illuminates the photocell, its resistance decreases to several hundred ohms, which raises the gate voltage of Q1, turning it on and supplying power to the lamp.
The described circuit utilizes a CdS photocell as a light-sensitive resistor that plays a critical role in controlling the operation of a lamp in response to the illumination from stage lights. The circuit is designed to operate in a wireless configuration, which enhances its usability in a theatrical setting where mobility and ease of installation are paramount.
In the off state, the high resistance of the CdS photocell ensures that the gate voltage of transistor Q1 remains low, preventing any current from flowing to the lamp. This condition is ideal when the stage is dark, as it conserves energy and minimizes unnecessary light emission. The use of a high-value resistor (Rl) in conjunction with the photocell is crucial, as it establishes a stable condition for the gate of Q1, ensuring that the transistor remains in the off state until it is activated by an adequate light source.
When the stage lights are turned on, the illumination from the spotlights causes a significant drop in the resistance of the CdS photocell. This transition allows for an increase in gate voltage at Q1, transitioning the transistor into its active state. As Q1 turns on, it permits current to flow through the lamp, illuminating it in synchronization with the stage lighting.
This design emphasizes simplicity and cost-effectiveness, as it relies on readily available components and does not require complex circuitry. The wireless aspect of the system can be achieved through the use of RF modules or other wireless communication methods, allowing for remote control and operation without the need for extensive wiring.
Overall, this schematic provides a functional and efficient solution for managing stage lighting in a school drama, ensuring that the lamps operate seamlessly in conjunction with the spotlights, enhancing the overall theatrical experience.A school drama needed lamps that automatically turned on and off when spot lights did the same. Lamp switching had to be wireless, durable, dependable, simple and inexpensive. With stage and spot lights off, very little light falls on the CdS photocell, so its internal resistance is several megohms and Rl keeps the gate of Ql at nearly zero volts, which keeps it off. When a spot or stage light hits the photocell, its resistance drops to several hundred ohms, raising Ql"s gate voltage, which turns it on and applies power to the lamp. 🔗 External reference
The described circuit utilizes a CdS photocell as a light-sensitive resistor that plays a critical role in controlling the operation of a lamp in response to the illumination from stage lights. The circuit is designed to operate in a wireless configuration, which enhances its usability in a theatrical setting where mobility and ease of installation are paramount.
In the off state, the high resistance of the CdS photocell ensures that the gate voltage of transistor Q1 remains low, preventing any current from flowing to the lamp. This condition is ideal when the stage is dark, as it conserves energy and minimizes unnecessary light emission. The use of a high-value resistor (Rl) in conjunction with the photocell is crucial, as it establishes a stable condition for the gate of Q1, ensuring that the transistor remains in the off state until it is activated by an adequate light source.
When the stage lights are turned on, the illumination from the spotlights causes a significant drop in the resistance of the CdS photocell. This transition allows for an increase in gate voltage at Q1, transitioning the transistor into its active state. As Q1 turns on, it permits current to flow through the lamp, illuminating it in synchronization with the stage lighting.
This design emphasizes simplicity and cost-effectiveness, as it relies on readily available components and does not require complex circuitry. The wireless aspect of the system can be achieved through the use of RF modules or other wireless communication methods, allowing for remote control and operation without the need for extensive wiring.
Overall, this schematic provides a functional and efficient solution for managing stage lighting in a school drama, ensuring that the lamps operate seamlessly in conjunction with the spotlights, enhancing the overall theatrical experience.A school drama needed lamps that automatically turned on and off when spot lights did the same. Lamp switching had to be wireless, durable, dependable, simple and inexpensive. With stage and spot lights off, very little light falls on the CdS photocell, so its internal resistance is several megohms and Rl keeps the gate of Ql at nearly zero volts, which keeps it off. When a spot or stage light hits the photocell, its resistance drops to several hundred ohms, raising Ql"s gate voltage, which turns it on and applies power to the lamp. 🔗 External reference