555 Timer Calculator


555 Timer Calculator

CHOOSE CONFIGURATION
_____ MILLISECONDS V cc R 2 R 1 S 1 C 1 C 2 8 (VCC) 4 (RESET) 7 (DISCHARGE) 6 (THRESHOLD) 2 (TRIGGER) 3 (OUT) 5 (CTRL V) 1 (GND) TRIGGER PULSE (S1) OUTPUT PULSE
R1 RESISTOR VALUE
C1 CAPACITANCE VALUE
FORMULA
OUTPUT PULSE DURATION
Through Hole Resistors
Chip Resistors - Surface Mount
Chassis Mount Resistors
Specialized Resistors
Ceramic Capacitors
Film Capacitors
Tantalum - Polymer Capacitors
Tantalum Capacitors
Mica and PTFE Capacitors
Niobium Oxide Capacitors
Aluminum - Polymer Capacitors
Aluminum Electrolytic Capacitors
Capacitor Networks, Arrays
Electric Double Layer Capacitors (EDLC), Supercapacitors
Silicon Capacitors
Thin Film Capacitors
Trimmers, Variable Capacitors
Clock/Timing - Programmable Timers and Oscillators
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PART NO.
MANUFACTURER
PRICE
STOCK
MIN QTY
DIGIKEY PART NO.
RESISTANCE
TOLERANCE
POWER (WATTS)
COMPOSITION
PACKAGE
CAPACITANCE
TOLERANCE
VOLTAGE - RATED
PACKAGE
FREQUENCY
VOLTAGE - SUPPLY
CURRENT - SUPPLY
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555 Timer Explained The 555-Timer IC (Integrated Circuit) is one of the most popular and widely spread ICs available with uses for nearly everything from clock timing, signal delay, pulse generation and signal oscillation applications. In Monostable mode the 555-timer IC forms a Resistance-Capacitance circuit with the external resistor and capacitor. When the input signal is applied to trigger pin, the internal workings of the IC start to charge the capacitor. When the voltage across the capacitor is equal to 2/3 the supply voltage of the IC the capacitor stops charging and the output signal of the circuit returns to the low state ready for the next input signal. The rectangular output waveform duration can be shortened or extended by adjusting the value of the resistor and capacitor, changing the rate that the capacitor charges. In Astable mode, the 555-timer forms a continuous output of rectangular waveform with a specific frequency with a fixed portions of the output signal in a high and low state with two resistors and one capacitor. When the 555-timer in astable mode is power on for the first time, the capacitor starts to charge with voltage, driving the output signal high. As the capacitor charges until it equals 2/3 the IC supply voltage. At that point, the capacitor starts to discharge, driving the output signal low. When the voltage across the capacitor drops to 1/3 of the IC supply voltage, it starts to charge up again driving the output signal high again and the process repeats again. As the capacitor charges and discharges voltage through the 555-timer IC, it switches between the two output states, High and Low. How much time is spent in those states and how quickly the cycle repeats is a function of both resistors and capacitor values. Examples Monostable The signal duration of the output can be modeled as Time in seconds (T) equal to the constant 1.1 multiplied by the resistance R measured in ohms (Ω) multiplied by the capacitance value C measured in Farads (F).
So, for a circuit with 10,000 (10k) ohms (Ω) of a resistance and a capacitance value of 1,000 microfarads (1000 µF), the total length of the output signal would be as follows
Astable The continuous output signal in Astable mode allows you to determine both the frequency in Hertz (Hz), how long it takes the signal to repeat and the duration of time the signal is in the high and low states. All three values that would define the output signal can be found using the values of R1 and R2 measured in ohms (Ω) and the capacitance value C1 measured in Farads (F).
So, for a circuit with resistors of 10,000 (10k) and 15,000 (15k) ohms (Ω) of a resistance and a capacitance value of 10 microfarads (10 µF), the output signal would have the following characteristics Time High
Time Low
Frequency

Optimize Your Circuit Plans with Our 555 Clock Calculator


The 555 clock IC is perhaps of the most well known and adaptable coordinated circuit utilized in gadgets. Known for its security and straightforwardness, it is broadly utilized in different applications like clocks, beat age, and oscillators. Our 555 Clock Mini-computer permits you to ascertain the qualities for astable and monostable setups, assisting you with saving time and configuration circuits with accuracy.


Why Utilize a 555 Clock Calculator?


Working out the parts for a 555 clock circuit physically can be dreary, particularly when you really want precision for explicit timing prerequisites. Our mini-computer improves on the interaction, permitting you to include part esteems and quickly see the outcomes for recurrence, obligation cycle, and result timing.


Key Elements of Our 555 Clock Calculator


Supports Both Astable and Monostable Modes


Our adding machine permits you to pick between astable (consistent result beat) and monostable (a single shot beat) modes, making it reasonable for different timing and heartbeat age applications.


Accurate and Moment Calculations


Come by exact outcomes right away, including recurrence, beat span, and obligation cycle. This is particularly valuable for fashioners and architects who need exact timing in their circuits.


Easy-to-Utilize Interface


Our easy to use mini-computer interface requires a couple of information values, for example, resistor and capacitor values, to in a split second produce results. This makes it simple for anybody to use, from understudies to proficient architects.


How to Utilize Our 555 Clock Calculator


  1. Select the Mode: Pick either astable or monostable mode relying upon your ideal output.
  2. Enter Part Values: Information the resistor and capacitor values as indicated by your circuit plan requirements.
  3. View the Results: The number cruncher will show the recurrence, time span, obligation cycle, or heartbeat width relying upon the chose mode.
  4. Example:
    For an astable mode arrangement with values:
    - R1 = 1kω
    - R2 = 10kω
    - C = 100µF
    The number cruncher will give the recurrence, obligation cycle, and time period.

Applications of the 555 Clock Calculator



Conclusion


Whether you are building a basic clock, making PWM signals, or creating complex timing circuits, our 555 Clock Number cruncher offers a quick and exact method for deciding the vital part esteems. Attempt it today to smooth out your circuit configuration process and guarantee ideal timing for each application.