The LM317 is an adjustable voltage linear regulator that can output 1.25 – 37V at up to 1.5A current with an input voltage range of 3 – 40V.
- LM317 Adjustable Voltage Regulator
KEY FEATURES OF LM317 ADJUSTABLE VOLTAGE REGULATOR:
- Adjustable voltage linear regulator
- 3 – 40V input voltage range
- 1.25 – 37V output voltage
- 1.5A continuous current with 2.2A surge capability
- TO-220 package
The LM317 is the most popular and one of the oldest variable linear regulator available. Input voltage can range from 3 – 40V and the output can be adjusted from 1.25V – 37V with an output current of up to 1.5A. They have built-in current limiting and over temperature protection and tend to be fairly robust devices.
The LM317 can be used to replace a number of different fixed voltage regulators when used for prototyping purposes. They can can also be easily wired up to make a simple low cost variable power supply for use in prototyping. We offer a simple small module built around the LM317 that can be used for the same purpose.
The LM317 is a 3-terminal floating regulator and does not have a ground pin as is found with most regulators. That allows for potentially very high voltages to be regulated as long as the maximum input-to-output voltage rating of 40V is not exceeded.
In place of a Ground pin, it has an Adjustment pin which uses a resistor divider network between the output terminal and ground to set the output voltage. These can be two fixed resistors if a fixed output voltage is desired, or one of the resistors can be variable potentiometer to allow the output to be adjusted over a range.
Unlike typical 78XX type regulators, the LM317 does require a minimum load current in order to fully regulate. This is typically less than 10mA so it is not typically an issue for most applications. A small load resistor could be placed on the output to guarantee a 10mA draw if was an issue.
The basic system does not necessarily require bypass capacitors, but if using it at a fair distance from the supply that is providing the input voltage, then a 0.1uF ceramic input filter capacitor should be added. A 1.0uF Tantalum or 20uF or larger electrolytic output capacitor can also be added to improve transient response if desired.
A basic circuit for hooking the LM317 up with an adjustable output is shown below.
Linear regulators have less ripple on their outputs compared to DC-DC converters that can be used for the same basic purpose, but the trade-off is that the linear regulators also tend to dissipate more heat in the process. The reason is that the linear regulator uses a series pass transistor on its output to drop the excess voltage.
The power dissipation of a linear regulator is dependent on the difference between the input voltage (Vin) and the output voltage (Vout) along with the amount of current that is being drawn from the regulator. The larger the voltage difference is between Vin and Vout, the higher the power dissipation will be which limits how much current can be drawn from the device.
The power dissipation of the LM317 device is easily calculated as Power Dissipation = (Vin – Vout) * Iout.
If the LM317 input is 15V and the output is adjusted to 10V and it is providing 1A of current, then Power Dissipation = (15V – 10V) * 1A = 5W. The LM317 TO-220 package will need to dissipate 5W of power. Under typical conditions, the device can dissipate about 1 – 1.25W before a heat sink becomes necessary, so in our example here, the device would definitely need a heat sink. Maximum output current without a heat sink in this case would be limited to about 250 – 300mA and the device will be running in the range of 85-95°C.
If you instead ran the LM317 off a 12V input, Power Dissipation = (12V – 10) * 1A = 2W. Still pretty warm, but much more manageable than 5W. With no heatsink you could draw 500-700mA.
As a general rule, you always want to use as low of an input voltage as possible to minimize power loss though the device and maximize the output current available.
- The tab of the LM317 is common with the Output pin.
- Under high current loads or with large input to output voltage differentials, the device can get very hot, so use care when handling.
|VIN||Max Input – Output V Differential||40V|
|IO||Maximum Output Current||1.5A (Typical)|
|IMAX||Peak Surge Current (typ)||2.2A|
|VO||Output Voltage||1.25V – 37V|
|VI – VO||Drop-out Voltage||3.0V (Max) 1.75V (Typ)|
|Package Type||Plastic Tab, 3-lead, through hole|