Variable-duty-cycle-timer
When configured as a free-running multivibrator, a 555 timer provides no more than a 50% duty cycle. By adding two transistors, however, it is possible to obtain a variable duty cycle ranging from 5% to 95% without altering the total duration of the on and off times. When the output voltage (VoUT) decreases, transistor Q1 is activated while transistor Q2 is deactivated, disconnecting the positive voltage supply (V+) as timing capacitor C2 discharges into pin 7 of the timer. Conversely, when VoUT increases, Q2 reconnects the positive voltage supply for the recharging of C2.
Adjusting the linear trimming potentiometer R3 to increase the charging resistance results in an increase in the on time, while simultaneously decreasing the off time by the same amount due to a reduction in the discharge resistance; the opposite effect occurs when the settings are reversed. Consequently, the total duration of the on and off times remains constant. Resistor R2 serves to protect Q2 and the timer from high charge and discharge currents.
The described circuit utilizes a 555 timer integrated circuit (IC) configured in astable mode, augmented by two bipolar junction transistors (BJTs) to enhance the duty cycle flexibility. The 555 timer operates by continuously switching between its high and low states, where the timing capacitor C2 charges and discharges through the resistive network formed by R2 and R3.
In this configuration, the duty cycle is determined by the ratio of the time the output is high to the total period of the output signal. The introduction of the two transistors allows for greater control over the charging and discharging times of C2. Q1 and Q2 are configured such that they operate in a complementary manner; when one is conducting, the other is cut off, thereby facilitating the timing function without altering the overall timing characteristics of the 555 timer.
The use of the linear trimming potentiometer R3 provides a method for fine-tuning the resistance, allowing for precise adjustments to the on and off times. This is particularly useful in applications where specific timing intervals are critical. The protective resistor R2 is essential for safeguarding the transistors and the 555 timer against potential damage from excessive current, thereby ensuring the longevity and reliability of the circuit.
This circuit design is applicable in various applications, including pulse width modulation (PWM) for motor control, LED dimming, and signal generation, where variable duty cycles are required. Proper selection of component values, particularly for R2, R3, and C2, will dictate the performance characteristics of the circuit, allowing for tailored timing solutions in electronic designs.When configured as a free-running multivibrator, a 555 timer provides no more than a 50% duty cycle. By adding two transistors, however, you can obtain a variable 5 to 95% duty cycle without changing the sum of the on and off times.
When VouT decreases, Ql is on and Q2 is off, disconnecting V + while timing capacitor C2 discharges into pin 7 of the timer. When VoUT increases, Q2 reconnects V + for recharging C2. Adjusting linear trimming potentiometer R3 to increase the charging resistance increases the on time, but decreases the off time by the same amount by lowering the discharge resistance (the converse is also true). As a result, the sum of the on and off times remains constant. R2 protects Q2 and the timer against high-charge/discharge currents 🔗 External reference
Adjusting the linear trimming potentiometer R3 to increase the charging resistance results in an increase in the on time, while simultaneously decreasing the off time by the same amount due to a reduction in the discharge resistance; the opposite effect occurs when the settings are reversed. Consequently, the total duration of the on and off times remains constant. Resistor R2 serves to protect Q2 and the timer from high charge and discharge currents.
The described circuit utilizes a 555 timer integrated circuit (IC) configured in astable mode, augmented by two bipolar junction transistors (BJTs) to enhance the duty cycle flexibility. The 555 timer operates by continuously switching between its high and low states, where the timing capacitor C2 charges and discharges through the resistive network formed by R2 and R3.
In this configuration, the duty cycle is determined by the ratio of the time the output is high to the total period of the output signal. The introduction of the two transistors allows for greater control over the charging and discharging times of C2. Q1 and Q2 are configured such that they operate in a complementary manner; when one is conducting, the other is cut off, thereby facilitating the timing function without altering the overall timing characteristics of the 555 timer.
The use of the linear trimming potentiometer R3 provides a method for fine-tuning the resistance, allowing for precise adjustments to the on and off times. This is particularly useful in applications where specific timing intervals are critical. The protective resistor R2 is essential for safeguarding the transistors and the 555 timer against potential damage from excessive current, thereby ensuring the longevity and reliability of the circuit.
This circuit design is applicable in various applications, including pulse width modulation (PWM) for motor control, LED dimming, and signal generation, where variable duty cycles are required. Proper selection of component values, particularly for R2, R3, and C2, will dictate the performance characteristics of the circuit, allowing for tailored timing solutions in electronic designs.When configured as a free-running multivibrator, a 555 timer provides no more than a 50% duty cycle. By adding two transistors, however, you can obtain a variable 5 to 95% duty cycle without changing the sum of the on and off times.
When VouT decreases, Ql is on and Q2 is off, disconnecting V + while timing capacitor C2 discharges into pin 7 of the timer. When VoUT increases, Q2 reconnects V + for recharging C2. Adjusting linear trimming potentiometer R3 to increase the charging resistance increases the on time, but decreases the off time by the same amount by lowering the discharge resistance (the converse is also true). As a result, the sum of the on and off times remains constant. R2 protects Q2 and the timer against high-charge/discharge currents 🔗 External reference