Popular IC's often used with Arduino:

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(A collection of all of these IC's is available here)


  • "2x or 4x, etc." means that there are multiple identical circuits that can be used within the same IC package.
  • Words with a small Upward Green Arrow are Clickable inks Like This to more information.
  • Most ICs have a printed or embossed DOT or MARK on their case that shows the location of Pin 1, or the end of the IC that has pin 1 (See LM324 and LM386 below).
  • Pins are numbered CounterClockWise from pin 1 as seen from the top. (Aside: WHY CounterClockwise? Answer: Because Vacuum Tubes were wired clockwise from the bottom!)
  • How To Read Device DataSheets (LINK)
  • JUMP to DIODES(click)
  • Using 555 as Power FET Driver (click)




LM393 2x comparator

A comparator is a device that compares two voltages and switches its digital output to indicate which is larger. It does it's comparison in the Analog domain and outputs it's result as a Digital value (1 or 0, High or Low). NOTE: This chip is the same as the LM339 but has 2 comparators.

ne5532-125.jpgne5532a-256.jpgNE5532 2x low-noise opamp

This IC contains two high-quality Operational Amplifiers. These amplifiers can be used in many applications in both AC and DC circuits. They are often used in professional audio systems as microphone preamplifiers etc. Their voltage gain can be set easily with two resistors.
Wikipedia has an excellent section showing Operational Amplifier Applications.




LM324 4x opamp single supply

This IC contains 4 Operational Amplifiers. It is optimized for operation from a single power supply and works well with a +5V supply for signals that work in that reduced voltage. This is a very popular Chip used in many applications.

LM386-125.jpgLM386 Audio amp low-voltageLM386-Pinout-256.jpg

This chip is widely used when medium-loud audio from a speaker or headphones is needed. Below is an example circuit.


NE555N-128.jpgNE555 Timer-General purposeNE555_Block_Diagram.jpg

The 555(Wikipedia) is one of the most versatile and popular Chips ever invented. The diagram on the right shows it's pinout and a useful diagram of it's functions. The 555 consists of a flip-flop that can be switched from OFF to ON, and a strong output driver that can source or sink 200 mA. It has two comparators (see above) that determine when the flip-flip is turned on or off. There are three 5K resistors in series inside the chips, connected from Vcc to Gnd and to the two comparators. By connecting various resistors and capacitors to the chip it can be used as a timer, as an oscillator, a driver for power FETs, a line driver, and for many other functions. Below are links to some favorite 555 sites showing circuit diagrams and functions.

555 and 556 Timer Circuits

555 Timer Tutorial



Random Nerd 555 TUTORIAL

555 AS POWER FET DRIVER (Right): A 555 is a good cheap driver for the high capacitance of a power NFET gate. The example diagram shows a 12 volt supply to drive Power FETs that have threshold voltages of 4 or 5 volts and need the gate driven to +10V or so for typical high current applications. NOTES:
  • The resistor from pin 5 to ground sets the input voltage thresholds for TTL / 5V signals such as Arduino.
  • This circuit INVERTS the input signal, so Arduino PWM will "work backward". Or: Fix It In Software.
  • Use a BIPOLAR version 555, NOT a CMOS version. Examples: NE555N etc. for high output capability.
  • NEED good bypass capacitors from 555 Vcc to Ground. Recommend .1 uf in parallel with 1 to 3.3 uF to handle the high output currents in the 555.

555 TRIVIA: Input Priorities of the 555

If you are using the 555 to do something unusual, you might need to know this:

Usually, when the 555 sees the TRIG pin go low (lower than half the CONT voltage), that sets the flip flop, and the output goes high.

Usually, when the 555 sees the THRESH pin go high (higher than CONT voltage), that clears the flip-flop and the output goes low.

Usually, (in most 555 circuits) the TRIG pin will be high again (higher than half of CONT) before anything happens at THRESH. But, if you are doing something Unusual, you might have a low signal at TRIG, and a signal at the THRESH pin that is higher than CONT at the same time. If that happens, you are telling the 555 both to set its output high, and to set its output low. In this case,TRIG being low wins and the output is set high.

In other words, TRIG is higher priority than THRESH. This also means that if TRIG is held low, THRESH is ignored.

One other important thing to know is that RES is the highest priority. RES being low always makes the output go low, no matter what is happening at TRIG and THRESH. TRIG and THRESH are both ignored if RES is low.



PC817 Opto-Isolatorpc817-125.jpg

This IC has an internal LED that can be driven from an Arduino output (with a series resistor of approximately 220 ohms). It has a phototransistor output which is turned ON when the LED is ON. (See pinout diagram on the right). There is no electrical connection between the input and output; only light crosses the barrier inside. This is excellent for connecting devices that have no common ground connection or operate at different voltages. This IC has a "Current Transfer Ratio" (ratio of LED current to output transistor current) of about 100.

4N25-35 Opto-Isolator4N25-125.jpg4N25-pinout-250.jpg

This is a popular Opto-Isolator electrically similar to the PC817 above.

MOC3061 Opto-TRIAC (0-crossing)MOC3061-pinout-256.jpgMOC3061M-125.jpg

This is another Opto-Isolator with an internal LED you can drive from an Arduino output. (Recommended series resistor: 150 to 220 ohms). This IC is designed to drive larger TRIACs (AC Power Line switching devices) while isolating the Microcomputer from the Power Line. It also switches at the points when the AC Power line is at Zero volts, greatly reducing noise and transients.


max485Pin-256.jpgMAX485 RS485 Transceiver max485-128.jpg

This IC is good for small networks or connecting to other RS485 devices. Multiple Transceivers can connect to the same 2-wire bus. There are also RS485 Modules Here:
More RS485 Information Here:
And here: http://www.maximintegrated.com/app-notes/index.mvp/id/723

ULN2003-pinout-256.jpgULN2003 7x Darlington Power DriverULN2003-128.jpg

This IC is used for driving devices like large LEDs, small motors, small Stepper motors, relay coils, etc. up to a voltage of 50V and a current of 500 mA for each output. Outputs can be paralleled for higher currents. It has "Open Collector" outputs which means it acts like a switch with one side connected to ground, also called a "Low Side Switch". It has built-in reverse-voltage protection diodes. There are 7 identical circuits.

1N4148 Fast-Switching Small Silicon Diode diode-diagram-256.jpg1N4148-128.jpg

This is a general-purpose diode rated at 100V and 300 mA. The end with the marked band is the "Cathode" which is the straight bar part of the diode symbol. A diode conducts current when the Anode is more positive than the Cathode, and blocks reverse current. More Information Here:
1N4007 (1 Amp 1000V) DATA SHEET:
1N5408 (3 Amp 1000V) DATA SHEET:

Digital ICs

These ICs operate at the 5V "CMOS/TTL" signal levels used by Arduino. They provide various digital logic functions.

74HC14.jpg74HC14 6x Inverter Schmitt-Trigger 74hc14-1-128.jpg

This very useful IC has 6 "Inverters" which means if the input is a 1 the output is a 0 and vice versa. Sometimes that function alone is needed, but this chip has two other common uses:
  • Make a weak signal into a strong one. (It takes very little input current and provides a strong output).
  • Remove noise from a noisy signal. (It has a "schmitt-trigger" property which means the input must go above a higher threshold to be seen as a 1 and a lower threshold to be seen as a 0. This is called "hysteresis". )
What if you just want to use those capabilities but not Invert the signal? Just put another inverter in series with the first one.
This chip can also be used to create digital delays, oscillators and other functions.

74HC595-pinout-256.jpg74HC595 Serial-In-Parallel-Out Expander 74hc595n-128.jpg

This IC is a Shift Register so that 8 bits of data can be 'shifted' into it over just 2 wires. This is often used to add more functional Digital Outputs to Arduino. It is most often controlled by the Arduino standard function shiftOut. See the Reference Page. Multiple 74HC595 chips can be connected in series so that the same 2 or 3 Arduino pins can control 8 or 16 or 24 etc. output bits.
Arduino shiftOut Tutorial

74HC165-pinout-256.jpg74HC165 Parallel-In-Serial-Out Expander74HC165-128.jpg

This IC is also a Shift Register. Now, 8 bits of data on Inputs (D0 to D7 on right) can be 'shifted' into Arduino over just 2 wires. This is often used to add more functional Digital Inputs to Arduino. It is most often controlled by the Arduino standard function shiftIn. See the Reference Page. Multiple 74HC165 chips can be connected in series so that the same 2 or 3 Arduino pins can read in data from 8 or 16 or 24 etc. input bits.
Arduino shiftIn Tutorial (Note: This tutorial shows a different chip.)