Decoupling capacitor: Difference between revisions

{{About|the use of capacitors to filter undesired noise from power supplies|the use of capacitors to allow AC signals to pass while blocking DC offsets|Capacitive coupling capacitor}}

AIn [[electronics]], a '''decoupling capacitor''' is a [[capacitor]] used to [[Decoupling_Decoupling (electronics)|decouple]] (i.e. prevent [[electrical energy]] from transferring to) one part of ana [[electrical network|circuit]] (circuit) from another. [[Noise (electronics)|Noise]] caused by other [[circuit elementselement]]s is shunted through the capacitor, reducing theits effect it has on the rest of the circuit. An{{anchor|Bypass capacitor}}For higher frequencies, an alternative name is '''bypass capacitor''' as it is used to bypass the [[power supply]] or other high-[[Electrical impedance|impedance]] component of a circuit.

Active devices of an [[electronic system]] (transistors,e.g. ICs[[transistor]]s, vacuum[[integrated tubescircuit]]s, for[[vacuum exampletube]]s) are connected to their [[power supplies]] through [[Electrical conductor|conductors]] with finite [[Electrical resistance and conductance|resistance]] and [[inductance]]. If the [[Electric current|current]] drawn by an active device changes, the [[voltage dropsdrop]] from the power supply to the device will also change due to these impedances[[Electrical impedance|impedance]]s. If several active devices share a common path to the power supply, changes in the current drawn by one element may produce voltage changes large enough to affect the operation of others -– [[voltage spike]]s or [[ground bounce]], for example -– so the change of state of one device is coupled to others through the common impedance to the power supply. A decoupling capacitor provides a bypass path for [[Transient response|transient]] currents, instead of flowing through the common impedance. <ref name=TTL75> Don Lancaster, ''TTL Cookbook', Howard W. Sams, 1975, no ISBN, pp.23-24 </ref>

The decoupling capacitor works as the device’s local [[Electric field|energy storage]]. The capacitor is placed between the power line and the [[Ground (electricity)|ground]] to the circuit thatthe current is to be provided. According to capacitor equation, ''i(t) = CdV(t)/dt'', voltage drop between power line and ground results in current draw out from the capacitor to the circuit and when capacitance ''C'' is large enough, sufficient current is supplied with acceptable range of voltage drop. To reduce the effective series inductance, small and large capacitors are usually placed in parallel; many small capacitors may be adjacent to individual integrated circuits. The[[Capacitor#Current–voltage relation|capacitor stores a small amount of energy that can compensate for the voltage drop in the power supply conductors to the capacitor.current–voltage relation]]

In digital circuits, decoupling capacitors also help prevent radiation of [[electromagnetic interference]] from relatively long circuit traces due to rapidly changing power supply currents.

Decoupling capacitors alone may not suffice in such cases as a high-power amplifier stage with a low-level pre-ampliferamplifier coupled to it. Care must be taken in the layout of circuit conductors so that heavy current ofat one stage dodoes not produce power supply voltage drops that affect other stages. TheThis may require re-routing printed circuit board traces to segregate circuits, or the use of a [[ground plane]] to improve the stability of power supply.

In a switching subcircuit, switching noisewill mustchange be suppressed. When athe load iscurrent applieddrawn tofrom a voltagethe source, it draws a certain amount of current. Typical power supply lines show inherent [[inductance]], which results in a slower response to changechanges in current. ThisThe in turn affects the transientsupply voltage levels,will sincedrop ifacross thethese loadparasitic currentinductances isfor zeroas thelong voltage acrossas the loadswitching isevent zero as welloccurs. This suddentransient voltage drop would be seen by other loads as well if the inductance between two loads is much lower compared to the inductance between the loads and the output capacitors of the power supply. This is only temporary; the inductor ultimately saturates (that is the magnetic field around the conductor reaches its max), the voltage drop across the inductor reaches zero, and the supply voltage comes back to normal. But even a temporary reduction in voltage can disturb adjacent subcircuits. Decoupling caps provide instantaneous current jolt which helps maintain constant voltage across a subcircuit (or provide a low impedance path for the transient currents; different descriptions are used by different industries).

To decouple other subcircuits from the effect of the sudden current demand, a decoupling capacitor can be placed betweenin theparallel supply voltage line and its reference (ground) next towith the switched load. While the load is switched outsubcircuit, theacross capacitor charges up to full powerits supply voltage andlines. otherwiseWhen doesswitching nothing.occurs Whenin the load is appliedsubcircuit, the capacitor initiallysupplies suppliesthe demandedtransient current. Ideally, by the time the capacitor runs out of charge, the powerswitching supplyevent linehas inductancefinished, isso saturated, andthat the load can draw full current at normal voltage from the power supply (and the capacitor can recharge too). Note that the voltage dip is reduced but not eliminated; i.e., the decoupling is not perfect and sometimes parallel combinations of caps are used to improve response. The best way to reduce switching noise is to design a [[Printed circuit board|PCB]] as a giant capacitor by sandwiching the power and ground planes across a [[dielectric]] material.{{Citation needed|date=August 2018}}

[[Transient (oscillation)|Transient]] [[Electrical load|load]] decoupling as described above is needed when there is a large load that gets switched quickly. The parasitic inductance in every (decoupling) capacitor may limit the suitable capacity and influence the appropriate type if switching occurs very fast.

These capacitors are often placed at each power source as well as at each analog component in order to ensure that the supplies are as steady as possible. Otherwise, an analog component with a poor [[power supply rejection ratio|power supply rejection ratio (PSRR)]] will copy fluctuations in the power supply onto its output.

In these applications, the decoupling capacitors are often called ''bypass capacitors'' to indicate that they provide an alternate path for high-frequency signals that would otherwise cause the normally steady suppliessupply voltage to movechange. Those components that require quick injections of current can ''bypass'' the power supply by receiving the current from the nearby capacitor. Hence, the slower power supply connection is used to charge these capacitors, and the capacitors actually provide the large quantities of high-availability current.

A transient load decoupling capacitor should usually beis placed as close as possible to the device requiring the decoupled signal. The goal is toThis minimizeminimizes the amount of line [[inductance]] and series [[Electrical resistance|resistance]] between the decoupling capacitor and thatthe device,. and theThe longer the conductor between the capacitor and the device, the more inductance there is present.<ref>[http://www.interfacebus.com/Design_Capacitors.html Capacitor Design Data, and Decoupling Placement, How-to] on [http://www.interfacebus.com/ Leroy's Engineering Web Site]</ref>

Since capacitors differ in their high-frequency characteristics (and capacitors with good high-frequency properties are often types with small capacity, while large capacitors usually have worse high-frequency response), decoupling oftenideally involves the use of a ''combination'' of capacitors. For example in logic circuits, a common arrangement is ~100 nF ceramic per logic IC (multiple ones for complex ICs), combined with [[Electrolytic capacitor|electrolytic]] or [[tantalum capacitor]](s) up to a few hundred μF per board /or board section.

* [https://web.archive.org/web/20120213101028/http://www.ultracadintersil.com/mentordata/esr%20and%20bypass%20capsan/an1325.pdf ESRChoosing and Bypass Capacitor Self Resonant Behavior: How to SelectUsing Bypass CapsCapacitors] &ndash; article writtenapplication bynote Douglasfrom BrooksIntersil

* [https://web.archive.org/web/20200224172143/http://www.hottconsultants.com/techtips/decoupling.html Decoupling] &ndash; decoupling guide for various frequencies by Henry W. Ott