78xx

78xx (sometimes L78xx, LM78xx, MC78xx...) is a family of self-contained fixed linear voltage regulator integrated circuits. The 78xx family is commonly used in electronic circuits requiring a regulated power supply due to their ease-of-use and low cost.

7805 in TO-220 and TO-92 packages
Internal dice of a Tesla MA7805

Nomenclature and packaging

For ICs within the 78xx family, the xx is replaced with two digits, indicating the output voltage (for example, the 7805 has a 5-volt output, while the 7812 produces 12 volts). The 78xx line are positive voltage regulators: they produce a voltage that is positive relative to a common ground. There is a related line of 79xx devices which are complementary negative voltage regulators. 78xx and 79xx ICs can be used in combination to provide positive and negative supply voltages in the same circuit.[1]

78xx ICs have three terminals and are commonly found in the TO-220 form factor, although they are available in surface-mount, TO-92, and TO-3 packages. These devices support an input voltage anywhere from around 2.5 volts over the intended output voltage up to a maximum of 35 to 40 volts depending on the model, and typically provide 1 or 1.5 amperes of current (though smaller or larger packages may have a lower or higher current rating).[2]

Family members

Typical application circuit for a simple power supply, showing transformer, bridge rectifier, 78xx regulator, and filter capacitors

78xx

There are common configurations for 78xx ICs, including 7805 (5 V), 7806 (6 V), 7808 (8 V), 7809 (9 V), 7810 (10 V), 7812 (12 V), 7815 (15 V), 7818 (18 V), and 7824 (24 V) versions. The 7805 is the most common, as its regulated 5-volt supply provides a convenient power source for most TTL components.

Less common are lower-power versions such as the LM78Mxx series (500 mA) and LM78Lxx series (100 mA) from National Semiconductor. Some devices provide slightly different voltages than usual, such as the LM78L62 (6.2 volts) and LM78L82 (8.2 volts) as well as the STMicroelectronics L78L33ACZ (3.3 volts).

The 7805 has been used in some ATX power supply designs for the +5 VSB (+5 V standby) output.[3]

79xx

The 79xx devices have a similar "part number" to "voltage output" scheme, but their outputs are negative voltage, for example 7905 is −5 V and 7912 is −12 V.

The 7905 and/or 7912 were popular in many older ATX power supply designs,[4][5] and some newer ATX power supplies may have a 7912.[6]

Unrelated devices

The LM78S40 from Fairchild is not part of the 78xx family and does not use the same design. It is a component in switching regulator designs and is not a linear regulator like other 78xx devices. The 7803SR from Datel is a full switching power supply module (designed as a drop-in replacement for 78xx chips), and not a linear regulator like the 78xx ICs.

Advantages

  • While external capacitors are typically required, 78xx series ICs do not require additional components to set their output voltage.[7] 78xx designs are simple in comparison to switch-mode power supply designs.[8]
  • 78xx series ICs have built-in protection against a circuit drawing too much current. They have protection against overheating and short-circuits, making them robust in most applications.[9]

Disadvantages

  • The input voltage must always be higher than the output voltage by some minimum amount (typically 2.5 volts). This can make these devices unsuitable for powering some devices from certain types of power sources (for example, powering a circuit that requires 5 volts using 6-volt batteries will not work using a 7805).[10] For input voltages closer to the output voltage, a pin-compatible low-dropout regulator (LDO) can be used instead.
  • As they are based on a linear regulator design, the input current required is always the same as the output current. As the input voltage must always be higher than the output voltage, this means that the total power (voltage multiplied by current) going into the 78xx will be more than the output power provided. The difference is dissipated as heat. This means both that for some applications an adequate heatsink must be provided, and also that a (often substantial) portion of the input power is wasted during the process, rendering them less efficient than some other types of power supplies. When the input voltage is significantly higher than the regulated output voltage (for example, powering a 7805 using a 24 volt power source), this inefficiency can be a significant issue.[11] Buck converters may be preferred over 78xx regulators because they are more efficient and do not require heat sinks, though they might be more expensive.
  • When using them in 'LM317 mode', with an R1/R2 voltage divider, note that the bias/adjust current drawn is several orders of magnitude higher (5 mA vs 50 μA), so this extra current makes the simple R1/R2 voltage division calculation less accurate for higher values of R.
gollark: Again, some examples of things needing some sort of balance DO NOT imply it is good or generally necessary.
gollark: This is just an example of "you sometimes need a quantity of something which falls in some interval", not a general proof.
gollark: That seems like just "it's bad because it's something you don't consent to" and also "it's unpleasant", which is I think what we said.
gollark: The dictionary will probably define it recursively or in a somewhat unsatisfying way.
gollark: No idea, hard to define rigorously.

See also

References

  1. Muhammad Rashid (13 January 2011). Power Electronics Handbook. Elsevier. pp. 609–. ISBN 978-0-12-382037-2.
  2. Balch, Mark (20 June 2003). Complete Digital Design : A Comprehensive Guide to Digital Electronics and Computer System Architecture: A Comprehensive Guide to Digital Electronics and Computer System Architecture. McGraw Hill Professional. ISBN 978-0-07-140927-8.
  3. "Maxpower PX-300W, 300-Watt ATX Power Supply Schematic".
  4. FSP145-60SP, 145-Watt ATX Power Supply Schematic.
  5. Delta Electronics DPS-260-2A, 260-Watt ATX Power Supply Schematic.
  6. "High-Efficiency 305-Watt ATX Reference Design Documentation Package" (PDF). ONSemi.com. ON Semiconductor.
  7. Electronic Circuit Analysis. Pearson Education India. 2012. pp. 14–. ISBN 978-81-317-5428-3.
  8. Oxer, Jonathan; Blemings, Hugh (28 December 2009). Practical Arduino: Cool Projects for Open Source Hardware. Apress. pp. 224–. ISBN 978-1-4302-2477-8.
  9. Biswanath, Paul (30 June 2014). Industrial Electronics and Control. PHI Learning Pvt. Ltd. pp. 35–. ISBN 978-81-203-4990-2.
  10. Warren Gay (17 September 2014). Mastering the Raspberry Pi. Apress. pp. 24–. ISBN 978-1-4842-0181-7.
  11. Charles Platt (19 October 2012). Encyclopedia of Electronic Components Volume 1: Resistors, Capacitors, Inductors, Switches, Encoders, Relays, Transistors. "O'Reilly Media, Inc.". pp. 163–. ISBN 978-1-4493-3387-4.

Datasheets

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