Easy-start-up-crystal-oscillator
This low-cost, crystal-controlled oscillator employs a single TTL gate. Two key factors facilitate the oscillator's start-up: the configuration of NAND gates G1, G2, and G3 in an unstable logic state, and the high loop gain provided by the three inverters. The values of R1, R2, C1, and C2 are not critical; they should be selected to ensure that the oscillator operates at a frequency 70 to 90% higher than the crystal frequency when the crystal is disconnected. For operation in the 1-2 MHz range, a low-power 54LOO IC is recommended; for 2-6 MHz, a standard 5400 type; and for 6-20 MHz, a 54HOO or 54SOO.
The described oscillator circuit utilizes a single TTL (Transistor-Transistor Logic) gate, specifically configured with three NAND gates (G1, G2, and G3) that form a feedback loop. This configuration is critical for generating oscillations, as it exploits the inherent instability of the logic gates when arranged in a specific manner. The feedback from the output of one gate to the input of another, combined with the high loop gain from the inverters, ensures that the circuit can initiate oscillation effectively.
The choice of resistors R1 and R2, along with capacitors C1 and C2, is flexible, allowing for adjustments based on the desired operating frequency. The recommendation to select component values that allow the oscillator to run at a frequency 70 to 90% higher than the crystal frequency when disconnected is crucial for ensuring reliable operation. This adjustment ensures that the circuit can still function effectively without the crystal, allowing for testing and tuning of the oscillator's performance.
For frequency ranges, specific integrated circuits are suggested to optimize performance. The use of a low-power 54LOO IC is recommended for frequencies between 1 to 2 MHz, which is suitable for applications requiring lower power consumption. For the 2-6 MHz range, a standard 5400 type IC is appropriate, offering a balance between power and performance. For higher frequency applications, specifically in the 6-20 MHz range, the 54HOO or 54SOO ICs are recommended, providing enhanced performance characteristics necessary for stable oscillation at these frequencies.
This oscillator design is well-suited for various applications, including clock generation, signal processing, and other electronic systems where precise frequency control is needed. Its simplicity and low cost make it an attractive choice for both hobbyists and professionals in the electronics field.This low cost, crystal-controlled oscillator uses one TTL gate. Two factors ensure oscillator start-up: The connection of NAND gates G1, G2, and G3 into an unstable logic configuration and the high loop gain of the three inverters. Values of R1, R2, C1, and C2 aren"t critical; select them so the oscillator operates at a frequency 70 to 90% higher than the crystal frequency when the crystal is disconnected. For 1-2 MHz operation, a low-power 54LOO IC is recommended; for a 2-6 MHz, a standard 5400 type; and for 6-20 MHz, a 54HOO or 54SOO.
🔗 External reference
The described oscillator circuit utilizes a single TTL (Transistor-Transistor Logic) gate, specifically configured with three NAND gates (G1, G2, and G3) that form a feedback loop. This configuration is critical for generating oscillations, as it exploits the inherent instability of the logic gates when arranged in a specific manner. The feedback from the output of one gate to the input of another, combined with the high loop gain from the inverters, ensures that the circuit can initiate oscillation effectively.
The choice of resistors R1 and R2, along with capacitors C1 and C2, is flexible, allowing for adjustments based on the desired operating frequency. The recommendation to select component values that allow the oscillator to run at a frequency 70 to 90% higher than the crystal frequency when disconnected is crucial for ensuring reliable operation. This adjustment ensures that the circuit can still function effectively without the crystal, allowing for testing and tuning of the oscillator's performance.
For frequency ranges, specific integrated circuits are suggested to optimize performance. The use of a low-power 54LOO IC is recommended for frequencies between 1 to 2 MHz, which is suitable for applications requiring lower power consumption. For the 2-6 MHz range, a standard 5400 type IC is appropriate, offering a balance between power and performance. For higher frequency applications, specifically in the 6-20 MHz range, the 54HOO or 54SOO ICs are recommended, providing enhanced performance characteristics necessary for stable oscillation at these frequencies.
This oscillator design is well-suited for various applications, including clock generation, signal processing, and other electronic systems where precise frequency control is needed. Its simplicity and low cost make it an attractive choice for both hobbyists and professionals in the electronics field.This low cost, crystal-controlled oscillator uses one TTL gate. Two factors ensure oscillator start-up: The connection of NAND gates G1, G2, and G3 into an unstable logic configuration and the high loop gain of the three inverters. Values of R1, R2, C1, and C2 aren"t critical; select them so the oscillator operates at a frequency 70 to 90% higher than the crystal frequency when the crystal is disconnected. For 1-2 MHz operation, a low-power 54LOO IC is recommended; for a 2-6 MHz, a standard 5400 type; and for 6-20 MHz, a 54HOO or 54SOO.
🔗 External reference