CircuitTikZ V. 0.3.0 Manual Circuit

User Manual:

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CircuiTikZ

version 0.3.0

Massimo A. Redaelli

December 30, 2012

Contents

1 Introduction 2

1.1 About................................... 3

1.2 Loadingthepackage........................... 3

1.3 License .................................. 3

1.4 Feedback ................................. 3

1.5 Requirements .............................. 3

1.6 Incompatible packages . . . . . . . . . . . . . . . . . . . . . . . . . 3

1.7 Introduction to version 0.3.0 . . . . . . . . . . . . . . . . . . . . . . 3

1.8 Introduction to version 0.2.3 . . . . . . . . . . . . . . . . . . . . . . 4

1.9 ConT

EXtcompatibility.......................... 4

2 Options 5

3 The components 6

3.1 Monopoles ................................ 7

3.2 Bipoles .................................. 8

3.2.1 Instruments ........................... 8

3.2.2 Basic resistive bipoles . . . . . . . . . . . . . . . . . . . . . . 8

3.2.3 Resistors and the like . . . . . . . . . . . . . . . . . . . . . . 9

3.2.4 Stationary sources . . . . . . . . . . . . . . . . . . . . . . . . 11

3.2.5 Diodesandsuch......................... 12

3.2.6 Basic dynamical bipoles . . . . . . . . . . . . . . . . . . . . . 13

3.2.7 Sinusoidal sources . . . . . . . . . . . . . . . . . . . . . . . . 15

3.2.8 Squaresources.......................... 15

3.2.9 Switch .............................. 15

3.3 Tripoles.................................. 15

3.3.1 Controlled sources . . . . . . . . . . . . . . . . . . . . . . . 15

3.3.2 Transistors............................ 17

3.3.3 Switch .............................. 19

3.3.4 Other bipole-like tripoles . . . . . . . . . . . . . . . . . . . . 20

3.3.5 Misc ............................... 20

3.4 Doublebipoles .............................. 20

3.5 Logicgates ................................ 21

3.6 Amplifiers ................................ 23

3.7 Supportshapes.............................. 24

4 Usage 24

4.1 Labels................................... 25

4.2 Currents ................................. 26

4.3 Voltages ................................. 27

4.3.1 Europeanstyle.......................... 27

4.3.2 Americanstyle.......................... 27

4.4 Nodes................................... 28

4.5 Specialcomponents ........................... 28

4.6 Integration with siunitx ........................ 30

4.7 Mirroring................................. 31

4.8 Putting them together . . . . . . . . . . . . . . . . . . . . . . . . . . 31

5 Not only bipoles 32

5.1 Anchors.................................. 32

5.1.1 Logicalports........................... 32

5.1.2 Transistors............................ 32

5.1.3 Othertripoles .......................... 34

5.1.4 Operational amplifier . . . . . . . . . . . . . . . . . . . . . . 35

5.1.5 Doublebipoles.......................... 36

5.2 Transistorpaths ............................. 36

6 Customization 37

6.1 Parameters................................ 37

6.2 Componentssize............................. 38

6.3 Colors................................... 39

7 FAQ 41

8 Examples 42

9 Revision history 45

Index of the components 48

1 Introduction

After two years of little exposure only on my personal website

, I did a major rehaul-

ing of the code of CircuiTikZ, fixing several problems and converting everything to

TikZ version 2.0.

’

m not too sure about the result, because my (La)T

X skills are much to be

improved, but it seems it’s time for more user feedback. So, here it is…

I know the documentation is somewhat scant. Hope to have time to improve it a

bit.

Now the package is moved to its own git repository:

https://github.com/mredaelli/

circuitikz. Contributions are welcome.

1.1 About

This package provides a set of macros for naturally typesetting electrical and (some-

what less naturally, perhaps) electronical networks.

It was born mainly for writing my own exercise book and exams sheets for the

Elettrotecnica courses at Politecnico di Milano, Italy. I wanted a tool that was easy

to use, with a lean syntax, native to L

X, and supporting directly PDF output format.

So I based everything with the very impressive (if somewhat verbose at times)

TikZ package.

1.2 Loading the package

\usepackage{circuitikz}

TikZ will be automatically loaded.

1.3 License

–

2011 Massimo Redaelli. This package is author-maintained. Per-

mission is granted to copy, distribute and/or modify this software under the terms

of the L

XProject Public License, version 1.3.1, or the GNU Public License. This soft-

ware is provided

‘

as is

’

, without warranty of any kind, either expressed or implied,

including, but not limited to, the implied warranties of merchantability and fitness

for a particular purpose.

1.4 Feedback

Much appreciated:

mailto:m.redaelli@gmail.com. Although I don

’

t guarantee

quick answers.

1.5 Requirements

•tikz, version ≥2;

•xstring, not older than 2009/03/13;

•siunitx, if using siunitx option.

1.6 Incompatible packages

None, as far as I know.

1.7 Introduction to version 0.3.0

Probably nobody is hoping or caring for a new version of the package at this point,

seeing how long it took me for this next release. But here it is, fixing a big problem

(voltage labels in the wrong place, in some cases) and adding several components.

Thanks for bug reporting and suggesting improvements.

1.8 Introduction to version 0.2.3

Having waited a long time before updating the package, many feature requests piled

on my desk. They should all be implemented now.

There are a number of backward incompatibilities

—

’

m sorry, but I had to make

a choice in order not to have a schizophrenic interface. They are mostly, in my

opinion, minor problems that can be dealt with with appropriate package options:

•potentiometer

is now the standard resistor-with-arrow-in-the-middle; the

old potentiometer is now known as

variable resistor

(or

), similarly to

variable inductor and variable capacitor;

•american inductor

was not really the standard american inductor. The old

american inductor has been renamed cute inductor;

•transformer

transformer core

and

variable inductor

are now linked

with the chosen type of inductor;

•

styles for selecting shape variants (like

[american resistors]

) are now in

the plural to avoid conflict with paths (like to[american resistor]).

1.9 ConT

EXt compatibility

As requested by some users, I fixed the package for it to be compatible with ConT

Xt.

Just use

\usemodule[circuitikz]

in your preamble and include the code between

\startcircuitikz

and

\endcircuitikz

. Please notice that the package

siunitx

in not available for ConT

Xt: the option

siunitx

simply defines a few measurement

units typical in electric sciences.

In actually using CircuiTikZ with TikZ version 2 in ConT

Xt an error comes up,

saying something like

! Undefined control sequence.

\tikz@cc@mid@checks -> \pgfutil@ifnextchar!

The solution has been suggested to me by Aditya Mahajan, and involves modifying

a file in TikZ:

Here is the fix. In tikzlibrarycalc.code.tex change

\def\tikz@cc@mid@checks{

\pgfutil@ifnextchar !{%AM: Added space

\tikz@cc@mid%

}{%

\advance\pgf@xa by\tikz@cc@factor\pgf@xb%

\advance\pgf@ya by\tikz@cc@factor\pgf@yb%

\tikz@cc@parse% continue

}

\def\tikz@cc@mid !{%AM Added space

\pgfutil@ifnextchar({%

\tikz@scan@one@point\tikz@cc@project%

}{%

\tikz@cc@mid@num%

}

As far as I know, this is a bug in TikZ, and I notified the author, but until he fixes

it, you know the workaround.

2 Options

•europeanvoltages

: uses arrows to define voltages, and uses european-style

voltage sources;

•americanvoltages

: uses

−

and

to define voltages, and uses american-style

voltage sources;

•europeancurrents: uses european-style current sources;

•americancurrents: uses american-style current sources;

•europeanresistors

: uses rectangular empty shape for resistors, as per eu-

ropean standards;

•americanresistors

: uses zig-zag shape for resistors, as per american stan-

dards;

•europeaninductors

: uses rectangular filled shape for inductors, as per eu-

ropean standards;

•americaninductors

: uses

”

4-bumps

”

shape for inductors, as per american

standards;

•cuteinductors

: uses my personal favorite,

”

pig-tailed

”

shape for inductors;

•americanports: uses triangular logic ports, as per american standards;

•europeanports: uses rectangular logic ports, as per european standards;

•european

: equivalent to

europeancurrents

europeanvoltages

europeanresistors

europeaninductors,europeanports;

•american

: equivalent to

americancurrents

americanvoltages

americanresistors

americaninductors,americanports;

•siunitx

: integrates with

SIunitx

package. If labels, currents or voltages are

of the form #1<#2> then what is shown is actually \SI{#1}{#2};

•nosiunitx: labels are not interpreted as above;

•fulldiodes

: the various diodes are drawn and filled by default, i.e. when

using styles such as

diode

…

Un-filled diode can always be forced with

Do,sDo, …

•emptydiodes

: the various diodes are drawn but not filled by default, i.e. when

using styles such as

diode

…

Filled diode can always be forced with

sD*, …

•arrowmos

: pmos and nmos have arrows analogous to those of pnp and npn

transistors;

•noarrowmos

: pmos and nmos do not have arrows analogous to those of pnp

and npn transistors;

•straighlabels

: labels on bipoles are always printed straigh up, i.e. with

horizontal baseline;

•rotatelabels

: labels on bipoles are always printed aligned along the bipole;

•smartlabels

: labels on bipoles are rotated along the bipoles, unless the

rotation is very close to multiples of 90°.

The old options in the singular (like

american voltage

) are still available for

compatibility, but are discouraged.

Loading the package with no options is equivalent to my own personal liking,

that is to the following options:

[europeancurrents, europeanvoltages, americanresistors, cuteinductors,

americanports, nosiunitx, noarrowmos, smartlabels].

In ConT

Xt the options are similarly specified:

current=european|american

voltage=european|american

resistor=american|european

inductor=cute|american|european

logic=american|european,siunitx=true|false,arrowmos=false|true.

3 The components

Here follows the list of all the shapes defined by CircuiTikZ. These are all

pgf

nodes,

so they are usable in both pgf and TikZ.

Each bipole (plus triac and thyristors) are shown using the following command,

where #1 is the name of the component2:

\begin{center}\begin{circuitikz} \draw

(0,0) to[ #1 ] (2,0)

; \end{circuitikz} \end{center}

The other shapes are shown with:

\begin{center}\begin{circuitikz} \draw

(0,0) node[ #1 ] {}

; \end{circuitikz} \end{center}

Please notice that for user convenience transistors can also be inputted using

the syntax for bipoles. See section 5.2.

If using the

\tikzexternalize

feature, as of Tikz 2.1 all pictures must end

with

\end{tikzpicture}

. Thus you cannot use the

circuitikz

environment.

Which is ok: just use tikzpicture: everything will work there just fine.

2If #1 is the name of the bipole/the style, then the actual name of the shape is #1shape.

3.1 Monopoles

• Ground (ground)

• Reference ground (rground)

• Signal ground (sground)

• Noiseless ground (nground)

• Protective ground (pground)

• Chassis ground3(cground)

• Antenna (antenna)

• Transmitting antenna (rxantenna)

3These last three were contributed by Luigi «Liverpool»)

• Receiving antenna (txantenna)

• Transmission line stub (tlinestub)

3.2 Bipoles

3.2.1 Instruments

• Ammeter (ammeter)

• Voltmeter (voltmeter)

3.2.2 Basic resistive bipoles

• Short circuit (short)

• Open circuit (open)

• Lamp (lamp)

• Generic (symmetric) bipole (generic)

• Tunable generic bipole (tgeneric)

• Generic asymmetric bipole (ageneric)

• Generic asymmetric bipole (full) (fullgeneric)

• Tunable generic bipole (full) (tfullgeneric)

• Memristor (memristor, or Mr)

3.2.3 Resistors and the like

If (default behaviour)

americanresistors

option is active (or the style

[american

resistors] is used), the resistor is displayed as follows:

• Resistor (R, or american resistor)

• Variable resistor (vR, or american variable resistor)

• Potentiometer (pR, or american potentiometer)

If instead

europeanresistors

option is active (or the style

[european resistors]

is used), the resistors, variable resistors and potentiometers are displayed as follows:

• Resistor (R, or european resistor)

• Variable resistor (vR, or european variable resistor)

• Potentiometer (pR, or european potentiometer)

Other miscellaneous resistor-like devices:

• Varistor (varistor)

• Photoresistor (phR, or photoresistor)

• Thermocouple (thermocouple)

• Thermistor (thR, or thermistor)

• PTC thermistor (thRp, or thermistor ptc)

• NTC thermistor (thRn, or thermistor ntc)

• Fuse (fuse)

• Asymmetric fuse (afuse, or asymmetric fuse)

3.2.4 Stationary sources

• Battery (battery)

• Single battery cell (battery1)

• Voltage source (european style) (european voltage source)

• Voltage source (american style) (american voltage source)

−

• Current source (european style) (european current source)

• Current source (american style) (american current source)

If (default behaviour)

europeancurrents

option is active (or the

style

[european currents]

is used), the shorthands

current source

isource

, and

are equivalent to

european current source

. Otherwise, if

americancurrents

option is active (or the style

[american currents]

used) they are equivalent to american current source.

Similarly, if (default behaviour)

europeanvoltages

option is active (or

the style

[european voltages]

is used), the shorthands

voltage source

vsource

, and

are equivalent to

european voltage source

. Otherwise, if

americanvoltages

option is active (or the style

[american voltages]

used) they are equivalent to american voltage source.

3.2.5 Diodes and such

• Empty diode (empty diode, or Do)

• Empty Schottky diode (empty Schottky diode, or sDo)

• Empty Zener diode (empty Zener diode, or zDo)

• Empty tunnel diode (empty tunnel diode, or tDo)

• Empty photodiode (empty photodiode, or pDo)

• Empty led (empty led, or leDo)

• Empty varcap (empty varcap, or VCo)

• Full diode (full diode, or D*)

• Full Schottky diode (full Schottky diode, or sD*)

• Full Zener diode (full Zener diode, or zD*)

• Full tunnel diode (full tunnel diode, or tD*)

• Full photodiode (full photodiode, or pD*)

• Full led (full led, or leD*)

• Full varcap (full varcap, or VC*)

The options

fulldiodes

and

emptydiodes

(and the styles

[full diodes]

and

[empty diodes]

) define which shape will be used by abbreviated com-

mands such that D,sD,zD,tD,pD,leD, and VC.

• Squid (squid)

• Barrier (barrier)

3.2.6 Basic dynamical bipoles

• Capacitor (capacitor, or C)

• Polar capacitor (polar capacitor, or pC)

• Variable capacitor (variable capacitor, or vC)

If (default behaviour)

cuteinductors

option is active (or the style

[cute inductors]

is used), the inductors are displayed as follows:

• Inductor (L, or cute inductor)

• Variable inductor (vL, or variable cute inductor)

americaninductors

option is active (or the style

[american inductors]

used), the inductors are displayed as follows:

• Inductor (L, or american inductor)

• Variable inductor (vL, or variable american inductor)

Finally, if

europeaninductors

option is active (or the style

[european inductors]

is used), the inductors are displayed as follows:

• Inductor (L, or european inductor)

• Variable inductor (vL, or variable european inductor)

There is also a transmission line:

• Transmission line (TL, or transmission line, tline)

3.2.7 Sinusoidal sources

Here because I was asked for them. But how do you distinguish one from the other?!

•

Sinusoidal voltage source (

sinusoidal voltage source

, or

vsourcesin,

sV)

•

Sinusoidal current source (

sinusoidal current source

, or

isourcesin,

sI)

3.2.8 Square sources

•

Square voltage source (

square voltage source

, or

vsourcesquare, sqV

)

3.2.9 Switch

• Closing switch (closing switch, or cspst)

• Opening switch (opening switch, or ospst)

• Push button (push button)

3.3 Tripoles

3.3.1 Controlled sources

Admittedly, graphically they are bipoles. But I couldn’t…

•

Controlled voltage source (european style) (

european controlled voltage

source)

•

Controlled voltage source (american style) (

american controlled voltage

source)

−

•

Controlled current source (european style) (

european controlled current

source)

•

Controlled current source (american style) (

american controlled current

source)

If (default behaviour)

europeancurrents

option is active (or the

style

[european currents]

is used), the shorthands

controlled current

source

cisource

, and

are equivalent to

european controlled current

source

. Otherwise, if

americancurrents

option is active (or the style

[american currents]

is used) they are equivalent to

american controlled

current source.

Similarly, if (default behaviour)

europeanvoltages

option is active (or the

style

[european voltages]

is used), the shorthands

controlled voltage

source

cvsource

, and

are equivalent to

european controlled voltage

source

. Otherwise, if

americanvoltages

option is active (or the style

[american voltages]

is used) they are equivalent to

american controlled

voltage source.

•

Controlled sinusoidal voltage source (

controlled sinusoidal voltage

source, or controlled vsourcesin, cvsourcesin, csV)

•

Controlled sinusoidal current source (

controlled sinusoidal current

source, or controlled isourcesin, cisourcesin, csI)

3.3.2 Transistors

• nmos (nmos)

• pmos (pmos)

• npn (npn)

• pnp (pnp)

• npigbt (nigbt)

• pigbt (pigbt)

If the option

arrowmos

is used (or after the commant

\ctikzset{tripoles/mos style/arrows}

is given), this is the output:

• nmos (nmos)

• pmos (pmos)

nfets and pfets have been incorporated based on code provided by Clemens

Helfmeier and Theodor Borsche:

• nfet (nfet)

• nigfete (nigfete)

• nigfetd (nigfetd)

• pfet (pfet)

• pigfete (pigfete)

• pigfetd (pigfetd)

njfet and pjfet have been incorporated based on code provided by Danilo Piazza-

lunga:

• njfet (njfet)

• pjfet (pjfet)

isfet

• isfet (isfet)

3.3.3 Switch

• spdt (spdt)

• Toggle switch (toggle switch)

3.3.4 Other bipole-like tripoles

The following tripoles are entered with the usual command of the form

• triac (triac, or Tr)

• thyristor (thyristor, or Ty)

3.3.5 Misc

• Mixer (mixer)

3.4 Double bipoles

Transformers automatically use the inductor shape currently selected. These are

the three possibilities:

• Transformer (cute inductor) (transformer)

• Transformer (american inductor) (transformer)

• Transformer (european inductor) (transformer)

Transformers with core are also available:

• Transformer core (cute inductor) (transformer core)

• Transformer core (american inductor) (transformer core)

• Transformer core (european inductor) (transformer core)

• Gyrator (gyrator)

3.5 Logic gates

• American and port (american and port)

• American or port (american or port)

• American not port (american not port)

• American nand port (american nand port)

• American nor port (american nor port)

• American xor port (american xor port)

• American xnor port (american xnor port)

• European and port (european and port)

• European or port (european or port)

≥1

• European not port (european not port)

• European nand port (european nand port)

• European nor port (european nor port)

≥1

• European xor port (european xor port)

= 1

• European xnor port (european xnor port)

= 1

If (default behaviour)

americanports

option is active (or the style

[american ports]

is used), the shorthands

and port

or port

not port

nand port

not port

xor port

, and

xnor port

are equivalent to the ameri-

can version of the respective logic port.

If otherwise

europeanports

option is active (or the style

[european

ports]

is used), the shorthands

and port

or port

not port

nand port

not port

xor port

, and

xnor port

are equivalent to the european version

of the respective logic port.

3.6 Amplifiers

• Operational amplifier (op amp)

−

• Fully differential operational amplifier4(fd op amp)

−

4Contributed by Kristofer M. Monisit.

• Plain amplifier (plain amp)

• Buffer (buffer)

3.7 Support shapes

• Arrows (current and voltage) (currarrow)

• Connected terminal (circ)

• Unconnected terminal (ocirc)

4 Usage

1\begin{ circuitikz }

2\draw (0,0) to[R, l=$R_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R=$R_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, v=$v_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R=$R_1$, i=$i_1$, v=$v_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R=$R_1$, i=$i_1$, v=$v_1$] (2,0);

3\end{circuitikz }

Long names/styles for the bipoles can be used:

1 kΩ 1\begin{ circuitikz }\draw

2(0,0) to[ resistor =1<\kilo\ohm>] (2,0)

3;\end{ circuitikz }

4.1 Labels

1\begin{ circuitikz }

2\draw (0,0) to[R, l^=$R_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, l_=$R_1$] (2,0);

3\end{circuitikz }

The default orientation of labels is controlled by the options

smartlabels

rotatelabels

and

straightlabels

(or the corresponding

label/align

keys). Here are examples

to see the differences:

135

180

-90

-45

-135

1\begin{ circuitikz }

2\ ctikzset { label /align = straight }

3\def\DIR{0,45,90,135,180,−90,−45,−135}

4\foreach \iin \DIR {

5\draw (0,0) to[R=\i, *−o] (\i:2.5);

7\end{circuitikz }

135

180

-90

-45

-135

1\begin{ circuitikz }

2\ ctikzset { label /align = rotate }

3\def\DIR{0,45,90,135,180,−90,−45,−135}

4\foreach \iin \DIR {

5\draw (0,0) to[R=\i, *−o] (\i:2.5);

7\end{circuitikz }

135

180

-90

-45

-135

1\begin{ circuitikz }

2\ ctikzset { label /align = smart}

3\def\DIR{0,45,90,135,180,−90,−45,−135}

4\foreach \iin \DIR {

5\draw (0,0) to[R=\i, *−o] (\i:2.5);

7\end{circuitikz }

4.2 Currents

1\begin{ circuitikz }

2\draw (0,0) to[R, i^>=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i_>=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i^<=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i_<=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i>^=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i>_=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i<^=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i<_=$i_1$] (2,0);

3\end{circuitikz }

Also

1\begin{ circuitikz }

2\draw (0,0) to[R, i<=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i>=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i^=$i_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, i_=$i_1$] (2,0);

3\end{circuitikz }

4.3 Voltages

4.3.1 European style

The default, with arrows. Use option

europeanvoltage

or style

[european voltages]

v11\begin{ circuitikz }[european voltages]

2\draw (0,0) to[R, v^>=$v_1$] (2,0);

3\end{circuitikz }

v11\begin{ circuitikz }[european voltages]

2\draw (0,0) to[R, v^<=$v_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }[european voltages]

2\draw (0,0) to[R, v_>=$v_1$] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }[european voltages]

2\draw (0,0) to[R, v_<=$v_1$] (2,0);

3\end{circuitikz }

4.3.2 American style

For those who like it (not me). Use option

americanvoltage

or set

[american voltages]

−+

v11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[R, v^>=$v_1$] (2,0);

3\end{circuitikz }

+−

v11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[R, v^<=$v_1$] (2,0);

3\end{circuitikz }

−+

1\begin{ circuitikz }[american voltages]

2\draw (0,0) to[R, v_>=$v_1$] (2,0);

3\end{circuitikz }

+−

1\begin{ circuitikz }[american voltages]

2\draw (0,0) to[R, v_<=$v_1$] (2,0);

3\end{circuitikz }

4.4 Nodes

1\begin{ circuitikz }

2\draw (0,0) to[R, o−o] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, −o] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, o−] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, *−*] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, −*] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, *−] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, o−*] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[R, *−o] (2,0);

3\end{circuitikz }

4.5 Special components

For some components label, current and voltage behave as one would expect:

a11\begin{ circuitikz }

2\draw (0,0) to[ I=$a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }

2\draw (0,0) to[ I , i=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }

2\draw (0,0) to[ cI=$k\cdot a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }

2\draw (0,0) to[ sI=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }

2\draw (0,0) to[ csI=$k\cdot a_1$] (2,0);

3\end{circuitikz }

The following results from using the option

americancurrent

or using the style

[american currents].

a11\begin{ circuitikz }[american currents]

2\draw (0,0) to[ I=$a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }[american currents]

2\draw (0,0) to[ I , i=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }[american currents]

2\draw (0,0) to[ cI=$k\cdot a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }[american currents]

2\draw (0,0) to[ sI=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }[american currents]

2\draw (0,0) to[ csI=$k\cdot a_1$] (2,0);

3\end{circuitikz }

The same holds for voltage sources:

a11\begin{ circuitikz }

2\draw (0,0) to[V=$a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }

2\draw (0,0) to[V, v=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }

2\draw (0,0) to[cV=$k\cdot a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }

2\draw (0,0) to[sV=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }

2\draw (0,0) to[csV=$k\cdot a_1$] (2,0);

3\end{circuitikz }

The following results from using the option

americanvoltage

or the style

[american voltages].

−

a11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[V=$a_1$] (2,0);

3\end{circuitikz }

−

a11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[V, v=$a_1$] (2,0);

3\end{circuitikz }

−

k·a11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[cV=$k\cdot a_1$] (2,0);

3\end{circuitikz }

a11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[sV=$a_1$] (2,0);

3\end{circuitikz }

k·a11\begin{ circuitikz }[american voltages]

2\draw (0,0) to[csV=$k\cdot a_1$] (2,0);

3\end{circuitikz }

4.6 Integration with siunitx

If the option

siunitx

is active (and not in ConT

Xt), then the following are equivalent:

1 kΩ 1\begin{ circuitikz }

2\draw (0,0) to[R, l=1<\kilo\ohm>] (2,0);

3\end{circuitikz }

1 kΩ 1\begin{ circuitikz }

2\draw (0,0) to[R, l=$\SI {1}{\ kilo\ohm}$] (2,0);

3\end{circuitikz }

1 mA 1\begin{ circuitikz }

2\draw (0,0) to[R, i=1<\milli\ampere>] (2,0);

3\end{circuitikz }

1 mA 1\begin{ circuitikz }

2\draw (0,0) to[R, i=$\SI {1}{\ milli \ampere}$] (2,0);

3\end{circuitikz }

1 V

1\begin{ circuitikz }

2\draw (0,0) to[R, v=1<\volt>] (2,0);

3\end{circuitikz }

1 V

1\begin{ circuitikz }

2\draw (0,0) to[R, v=$\SI {1}{\ volt }$] (2,0);

3\end{circuitikz }

4.7 Mirroring

1\begin{ circuitikz }

2\draw (0,0) to[pD] (2,0);

3\end{circuitikz }

1\begin{ circuitikz }

2\draw (0,0) to[pD, mirror] (2,0);

3\end{circuitikz }

At the moment, placing labels and currents on mirrored bipoles works:

T1\begin{ circuitikz }

2\draw (0,0) to[ospst=T] (2,0);

3\end{circuitikz }

i11\begin{ circuitikz }

2\draw (0,0) to[ospst=T, mirror, i=$i_1$] (2,0);

3\end{circuitikz }

But voltages don’t:

v1\begin{ circuitikz }

2\draw (0,0) to[ospst=T, mirror, v=v] (2,0);

3\end{circuitikz }

Sorry about that.

4.8 Putting them together

1 kΩ

1 mA

1\begin{ circuitikz }

2\draw (0,0) to[R=1<\kilo\ohm>,

3i>_=1<\ milli\ampere>, o−*] (3,0);

4\end{circuitikz }

1 mA 1\begin{ circuitikz }

2\draw (0,0) to[D*, v=$v_D$,

3i=1<\ milli \ampere>, o−*] (3,0);

4\end{circuitikz }

5 Not only bipoles

Since only bipoles (but see section 5.2) can be placed

”

along a line

”

, components

with more than two terminals are placed as nodes:

1\tikz \node[npn] at (0,0) {};

5.1 Anchors

In order to allow connections with other components, all components define anchors.

5.1.1 Logical ports

All logical ports, except not, have two inputs and one output. They are called

respectively in 1,in 2,out:

1\begin{ circuitikz } \draw

2(0,0) node[and port] (myand) {}

3(myand.in 1) node[anchor=east] {1}

4(myand.in 2) node[anchor=east] {2}

5(myand.out) node[anchor=west] {3}

6;\end{ circuitikz }

1\begin{ circuitikz } \draw

2(0,2) node[and port] (myand1) {}

3(0,0) node[and port] (myand2) {}

4(2,1) node[xnor port] (myxnor) {}

5(myand1.out) −| (myxnor.in 1)

6(myand2.out) −| (myxnor.in 2)

7;\end{ circuitikz }

In the case of not, there are only

and

out

(although for compatibility reasons

in 1 is still defined and equal to in):

1\begin{ circuitikz } \draw

2(1,0) node[not port] (not1) {}

3(3,0) node[not port] (not2) {}

4(0,0) −− (not1.in)

5(not2.in) −− (not1.out)

6++(0,−1) node[ground] {} to[C] (not1.out)

7(not2.out) −| (4,1) −| (0,0)

8;\end{ circuitikz }

5.1.2 Transistors

For nmos, pmos, nfet, nigfete, nigfetd, pfet, pigfete, and pigfetd transistors one has

base

gate

source

and

drain

anchors (which can be abbreviated with

and

D):

1\begin{ circuitikz } \draw

2(0,0) node[nmos] (mos) {}

3(mos.base) node[anchor=west] {B}

4(mos.gate) node[anchor=east] {G}

5(mos.drain) node[anchor=south] {D}

6(mos.source) node[anchor=north] {S}

7;\end{ circuitikz }

1\begin{ circuitikz } \draw

2(0,0) node[pigfete] ( pigfete ) {}

3( pigfete .B) node[anchor=west] {B}

4( pigfete .G) node[anchor=east] {G}

5( pigfete .D) node[anchor=south] {D}

6( pigfete .S) node[anchor=north] {S}

7;\end{ circuitikz }

Similarly njfet and pjfet have

gate

source

and

drain

anchors (which can be

abbreviated with G,Sand D):

S1\begin{ circuitikz } \draw

2(0,0) node[pjfet ] ( pjfet ) {}

3( pjfet .G) node[anchor=east] {G}

4( pjfet .D) node[anchor=north] {D}

5( pjfet .S) node[anchor=south] {S}

6;\end{ circuitikz }

For npn, pnp, nigbt, and pigbt transistors the anchors are

base

emitter

and

collector anchors (which can be abbreviated with B,Eand C):

1\begin{ circuitikz } \draw

2(0,0) node[npn] (npn) {}

3(npn.base) node[anchor=east] {B}

4(npn. collector ) node[anchor=south] {C}

5(npn.emitter) node[anchor=north] {E}

6;\end{ circuitikz }

E1\begin{ circuitikz } \draw

2(0,0) node[pigbt] (pigbt) {}

3(pigbt .B) node[anchor=east] {B}

4(pigbt .C) node[anchor=north] {C}

5(pigbt .E) node[anchor=south] {E}

6;\end{ circuitikz }

Here is one composite example (please notice that the

xscale=-1

style would

also reflect the label of the transistors, so here a new node is added and its text is

used, instead of that of pnp1):

1\begin{ circuitikz } \draw

2(0,0) node[pnp] (pnp2) {2}

3(pnp2.B) node[pnp, xscale=−1, anchor=B] (pnp1) {}

4(pnp1) node {1}

5(pnp1.C) node[npn, anchor=C] (npn1) {}

6(pnp2.C) node[npn, xscale=−1, anchor=C] (npn2) {}

7(pnp1.E) −− (pnp2.E) (npn1.E) −− (npn2.E)

8(pnp1.B) node[circ] {} |−(pnp2.C) node[circ] {}

9;\end{ circuitikz }

Similarly, transistors and other components can be reflected vertically:

S1\begin{ circuitikz } \draw

2(0,0) node[pigfete , yscale=−1] ( pigfete ) {}

3( pigfete .B) node[anchor=west] {B}

4( pigfete .G) node[anchor=east] {G}

5( pigfete .D) node[anchor=north] {D}

6( pigfete .S) node[anchor=south] {S}

7;\end{ circuitikz }

1\begin{ circuitikz }

2\draw (0,2)

3node[rground, yscale=−1] {}

4to[R=$R_1$] (0,0)

5node[sground] {};

6\end{circuitikz }

5.1.3 Other tripoles

When inserting a thrystor, a triac or a potentiometer, one needs to refer to the third

node

—

gate (

gate

) for the former two; wiper (

wiper

) for the latter one.

This is done by giving a name to the bipole:

1\begin{ circuitikz } \draw

2(0,0) to[Tr, n=TRI] (2,0)

3to[pR, n=POT] (4,0);

4\draw[dashed] (TRI.G) −| (POT.wiper)

5;\end{ circuitikz }

As for the switches:

in out 1

out 2

1\begin{ circuitikz } \draw

2(0,0) node[spdt] (Sw) {}

3(Sw.in) node[left ] {in}

4(Sw.out 1) node[right] {out 1}

5(Sw.out 2) node[right] {out 2}

6;\end{ circuitikz }

1\begin{ circuitikz } \draw

2(0,0) to[C] (1,0) to[toggle switch , n=Sw] (2.5,0)

3−− (2.5,−1) to[battery1] (1.5,−1) to[R] (0,−1) −| (0,0)

4(Sw.out 2) −| (2.5, 1) to[R] (0,1) −− (0,0)

5;\end{ circuitikz }

And the mixer:

in 1

in 2

out

1\begin{ circuitikz } \draw

2(0,0) node[mixer] (mix) {}

3(mix.in 1) node[left ] {in 1}

4(mix.in 2) node[below] {in 2}

5(mix.out) node[right] {out}

6;\end{ circuitikz }

5.1.4 Operational amplifier

The op amp defines the inverting input (

), the non-inverting input (

) and the

output (out) anchors:

−

v−

1\begin{ circuitikz } \draw

2(0,0) node[op amp] (opamp) {}

3(opamp.+) node[left ] {$v_+$}

4(opamp.−) node[left] {$v_−$}

5(opamp.out) node[right] {$v_o$}

6;\end{ circuitikz }

There are also two more anchors defined, up and down, for the power supplies:

−

v−

12 V

1\begin{ circuitikz } \draw

2(0,0) node[op amp] (opamp) {}

3(opamp.+) node[left ] {$v_+$}

4(opamp.−) node[left] {$v_−$}

5(opamp.out) node[right] {$v_o$}

6(opamp.down) node[ground] {}

7(opamp.up) ++ (0,.5) node[above] {\SI {12}{\ volt }}

8−− (opamp.up)

9;\end{ circuitikz }

The fully differential op amp defines two outputs:

−

v−out +

out -

1\begin{ circuitikz } \draw

2(0,0) node[fd op amp] (opamp) {}

3(opamp.+) node[left ] {$v_+$}

4(opamp.−) node[left] {$v_−$}

5(opamp.out +) node[right] {out +}

6(opamp.out −) node[right] {out −}

7(opamp.down) node[ground] {}

8;\end{ circuitikz }

5.1.5 Double bipoles

All the (few, actually) double bipoles/quadrupoles have the four anchors, two for

each port. The first port, to the left, is port

, having the anchors

(up) and

(down); same for port B. They also expose the base anchor, for labelling:

1\begin{ circuitikz } \draw

2(0,0) node[transformer] (T) {}

3(T.A1) node[anchor=east] {A1}

4(T.A2) node[anchor=east] {A2}

5(T.B1) node[anchor=west] {B1}

6(T.B2) node[anchor=west] {B2}

7(T.base) node{K}

8;\end{ circuitikz }

1\begin{ circuitikz } \draw

2(0,0) node[gyrator] (G) {}

3(G.A1) node[anchor=east] {A1}

4(G.A2) node[anchor=east] {A2}

5(G.B1) node[anchor=west] {B1}

6(G.B2) node[anchor=west] {B2}

7(G.base) node{K}

8;\end{ circuitikz }

5.2 Transistor paths

For syntactical convenience transistors can be placed using the normal path notation

used for bipoles. The transitor type can be specified by simply adding a

“

”

(for

transistor) in front of the node name of the transistor. It will be placed with the

base/gate orthogonal to the direction of the path:

231\begin{ circuitikz } \draw

2(0,0) node[njfet ] {1}

3(−1,2) to[ Tnjfet =2] (1,2)

4to[ Tnjfet =3, mirror] (3,2);

5;\end{ circuitikz }

Access to the gate and/or base nodes can be gained by naming the transistors

with the nor name path style:

1\begin{ circuitikz } \draw[yscale =1.1, xscale =.8]

2(2,4.5) −− (0,4.5) to[Tpmos, n=p1] (0,3)

3to[Tnmos, n=n1] (0,1.5)

4to[Tnmos, n=n2] (0,0) node[ground] {}

5(2,4.5) to[Tpmos,n=p2] (2,3) to[short, −*] (0,3)

6(p1.G) −− (n1.G) to[short, *−o] ($(n1.G )+(3,0)$)

7(n2.G) ++(2,0) node[circ] {} −| (p2.G)

8(n2.G) to[short, −o] ($(n2.G )+(3,0)$)

9(0,3) to[short, −o] (−1,3)

10 ;\end{ circuitikz }

The

name

property is available also for bipoles, although this is useful mostly for

triac, potentiometer and thyristor (see 3.3.4).

6 Customization

6.1 Parameters

Pretty much all CircuiTikZ relies heavily on

pgfkeys

for value handling and con-

figuration. Indeed, at the beginning of

circuitikz.sty

a series of key definitions

can be found that modify all the graphical characteristics of the package.

All can be varied using the \ctikzset command, anywhere in the code.

Shape of the components (on a per-component-class basis)

1 Ω

1\tikz \draw (0,0) to[R=1<\ohm>] (2,0); \par

2\ ctikzset { bipoles/ resistor /height=.6}

3\tikz \draw (0,0) to[R=1<\ohm>] (2,0);

1\tikz \draw (0,0) node[nand port] {}; \par

2\ ctikzset { tripoles /american nand port/input height=.2}

3\ ctikzset { tripoles /american nand port/port width=.2}

4\tikz \draw (0,0) node[nand port] {};

Thickness of the lines (globally)

1 F

1\tikz \draw (0,0) to[C=1<\farad>] (2,0); \par

2\ ctikzset { bipoles/thickness=1}

3\tikz \draw (0,0) to[C=1<\farad>] (2,0);

Global properties Of voltage and current

1 V

1\tikz \draw (0,0) to[R, v=1<\volt>] (2,0); \par

2\ ctikzset {voltage/distance from node=.1}

3\tikz \draw (0,0) to[R, v=1<\volt>] (2,0);

1\tikz \draw (0,0) to[C, i=$\imath$] (2,0); \par

2\ ctikzset {current/distance = .2}

3\tikz \draw (0,0) to[C, i=$\imath$] (2,0);

However, you can override the properties

voltage/distance from node5

voltage/bump b6

and voltage/european label distance7on a per-component basis, in order to

fine-tune the voltages:

1 V 2 V

1\tikz \draw (0,0) to[R, v=1<\volt>] (1.5,0)

2to[C, v=2<\volt>] (3,0); \par

3\ ctikzset { bipoles/capacitor/voltage/%

4distance from node/. initial =.7}

5\tikz \draw (0,0) to[R, v=1<\volt>] (1.5,0)

6to[C, v=2<\volt>] (3,0); \par

Admittedly, not all graphical properties have understandable names, but for the

time it will have to do:

1\tikz \draw (0,0) node[xnor port] {};

2\ ctikzset { tripoles /american xnor port/aaa=.2}

3\ ctikzset { tripoles /american xnor port/bbb=.6}

4\tikz \draw (0,0) node[xnor port] {};

6.2 Components size

Perhaps the most important parameter is

\circuitikzbasekey/bipoles/length

which can be interpreted as the length of a resistor (including reasonable connec-

tions): all other lenghts are relative to this value. For instance:

5That is, how distant from the initial and final points of the path the arrow starts and ends.

6Controlling how high the bump of the arrow is — how curved it is.

7Controlling how distant from the bipole the voltage label will be.

20 Ω

10 Ω

5vx

5 Ω

1\ ctikzset { bipoles/length=1.4cm}

2\begin{ circuitikz }[ scale =1.2]\ draw

3(0,0) node[anchor=east] {B}

4to[short, o−*] (1,0)

5to[R=20<\ohm>, *−*] (1,2)

6to[R=10<\ohm>, v=$v_x$] (3,2) −− (4,2)

7to[ cI=$\frac{\ si {\siemens}}{5} v_x$, *−*] (4,0) −− (3,0)

8to[R=5<\ohm>, *−*] (3,2)

9(3,0) −− (1,0)

10 (1,2) to[short, −o] (0,2) node[anchor=east]{A}

11 ;\end{ circuitikz }

20 Ω

10 Ω

5vx

5 Ω

1\ ctikzset { bipoles/length=.8cm}

2\begin{ circuitikz }[ scale =1.2]\ draw

3(0,0) node[anchor=east] {B}

4to[short, o−*] (1,0)

5to[R=20<\ohm>, *−*] (1,2)

6to[R=10<\ohm>, v=$v_x$] (3,2) −− (4,2)

7to[ cI=$\frac{\siemens}{5} v_x$, *−*] (4,0) −− (3,0)

8to[R=5<\ohm>, *−*] (3,2)

9(3,0) −− (1,0)

10 (1,2) to[short, −o] (0,2) node[anchor=east]{A}

11 ;\end{ circuitikz }

6.3 Colors

The color of the components is stored in the key

\circuitikzbasekey/color

CircuiTikZ tries to follow the color set in TikZ, although sometimes it fails. If you

change color in the picture, please do not use just the color name as a style, like

[red], but rather assign the style [color=red].

Compare for instance

1\begin{ circuitikz } \draw[red]

2(0,2) node[and port] (myand1) {}

3(0,0) node[and port] (myand2) {}

4(2,1) node[xnor port] (myxnor) {}

5(myand1.out) −| (myxnor.in 1)

6(myand2.out) −| (myxnor.in 2)

7;\end{ circuitikz }

and

1\begin{ circuitikz } \draw[color=red]

2(0,2) node[and port] (myand1) {}

3(0,0) node[and port] (myand2) {}

4(2,1) node[xnor port] (myxnor) {}

5(myand1.out) −| (myxnor.in 1)

6(myand2.out) −| (myxnor.in 2)

7;\end{ circuitikz }

One can of course change the color in medias res:

1\begin{ circuitikz } \draw

2(0,0) node[pnp, color=blue] (pnp2) {}

3(pnp2.B) node[pnp, xscale=−1, anchor=B, color=brown] (pnp1) {}

4(pnp1.C) node[npn, anchor=C, color=green] (npn1) {}

5(pnp2.C) node[npn, xscale=−1, anchor=C, color=magenta] (npn2) {}

6(pnp1.E) −− (pnp2.E) (npn1.E) −− (npn2.E)

7(pnp1.B) node[circ] {} |−(pnp2.C) node[circ] {}

8;\end{ circuitikz }

The all-in-one stream of bipoles poses some challanges, as only the actual body

of the bipole, and not the connecting lines, will be rendered in the specified color.

Also, please notice the curly braces around the to:

1 V

1 Ω

1 F

1\begin{ circuitikz } \draw

2(0,0) to[V=1<\volt>] (0,2)

3{ to[R=1<\ohm>, color=red] (2,2) }

4to[C=1<\farad>] (2,0) −− (0,0)

5;\end{ circuitikz }

Which, for some bipoles, can be frustrating:

1 V

1 Ω

1 F

1\begin{ circuitikz } \draw

2(0,0){ to[V=1<\volt>, color=red] (0,2) }

3to[R=1<\ohm>] (2,2)

4to[C=1<\farad>] (2,0) −− (0,0)

5;\end{ circuitikz }

The only way out is to specify different paths:

1 V

1 Ω

1 F

1\begin{ circuitikz } \draw[color=red]

2(0,0) to[V=1<\volt>, color=red] (0,2);

3\draw (0,2) to[R=1<\ohm>] (2,2)

4to[C=1<\farad>] (2,0) −− (0,0)

5;\end{ circuitikz }

And yes: this is a bug and not a feature…

7 FAQ

Q: When using \tikzexternalize I get the following error:

! Emergency stop.

A: The TikZ manual states:

Furthermore, the library assumes that all L

X pictures are ended

with \end{tikzpicture}\verb.

Just substitute every occurrence of the environment

circuitikz

with

tikzpicture

They are actually pretty much the same.

Q: How do I draw the voltage between two nodes?

A: Between any two nodes there is an open circuit!

1\begin{ circuitikz } \draw

2node[ocirc] (A) at (0,0) {}

3node[ocirc] (B) at (2,1) {}

4(A) to[open, v=$v$] (B)

5;\end{ circuitikz }

Q: I cannot write to[R = $R_1=12V$] nor to[ospst = open, 3s]: I get errors.

A: It is a limitation of the TikZ parser. Use

to[R = $R_1{=}12V$]

and

to[ospst = open{,} 3s]

instead.

8 Examples

10 µF

2.2 kΩ

12 mH

1 kΩ

0.3 kΩi1

1 mA

1\begin{ circuitikz }[ scale =1.4]\ draw

2(0,0) to[C, l=10<\micro\farad>] (0,2) −− (0,3)

3to[R, l =2.2<\ kilo\ohm>] (4,3) −− (4,2)

4to[L, l=12<\ milli\henry>, i=$i_1$] (4,0) −− (0,0)

5(4,2) { to[D*, *−*, color=red] (2,0) }

6(0,2) to[R, l=1<\kilo\ohm>, *−] (2,2)

7to[cV, v=$\SI {.3}{\ kilo\ohm} i_1$] (4,2)

8(2,0) to[ I , i=1<\milli\ampere>, −*] (2,2)

9;\end{ circuitikz }

e(t)

4 nF

0.25 kΩ

1 kΩ

2 nF a(t)

2 mH

1 2 3

1\begin{ circuitikz }[ scale =1.2]\ draw

2(0,0) node[ground] {}

3to[V=$e(t )$, *−*] (0,2) to[C=4<\nano\farad>] (2,2)

4to[R, l _=.25<\ kilo\ohm>, *−*] (2,0)

5(2,2) to[R=1<\kilo\ohm>] (4,2)

6to[C, l_=2<\nano\farad>, *−*] (4,0)

7(5,0) to[ I , i_=$a(t )$, −*] (5,2) −− (4,2)

8(0,0) −− (5,0)

9(0,2) −− (0,3) to[L, l=2<\milli \henry>] (5,3) −− (5,2)

11 {[anchor=south east] (0,2) node {1} (2,2) node {2} (4,2) node {3}}

12 ;\end{ circuitikz }

20 Ω

10 Ω

5vx

5 Ω

1\begin{ circuitikz }[ scale =1.2]\ draw

2(0,0) node[anchor=east] {B}

3to[short, o−*] (1,0)

4to[R=20<\ohm>, *−*] (1,2)

5to[R=10<\ohm>, v=$v_x$] (3,2) −− (4,2)

6to[ cI=$\frac{\siemens}{5} v_x$, *−*] (4,0) −− (3,0)

7to[R=5<\ohm>, *−*] (3,2)

8(3,0) −− (1,0)

9(1,2) to[short, −o] (0,2) node[anchor=east]{A}

10 ;\end{ circuitikz }

1\begin{ circuitikz }[ scale =1]\draw

2(0,0) node[transformer] (T) {}

3(T.B2) to[pD] ($(T.B 2)+(2,0)$) −| (3.5, −1)

4(T.B1) to[pD] ($(T.B 1)+(2,0)$) −| (3.5, −1)

5;\end{ circuitikz }

−

Uwe

RdRd

Cd2

Cd1

Uwy

1\begin{ circuitikz }[ scale =1]\draw

2(5,.5) node [op amp] (opamp) {}

3(0,0) node [ left ] {$U_{we}$} to [R, l=$R_d$, o−*] (2,0)

4to [R, l=$R_d$, *−*] (opamp.+)

5to [C, l_=$C_{d2}$, *−] ($(opamp.+)+(0,−2)$) node [ground] {}

6(opamp.out) |−(3.5,2) to [C, l_=$C_{d1}$, *−] (2,2) to [short] (2,0)

7(opamp.−)−| (3.5,2)

8(opamp.out) to [short, *−o] (7,.5) node [right ] {$U_{wy}$}

9;\end{ circuitikz }

1 mA

2 kΩ

−

2 V

−

4 V

1 kΩ

v1/V

i1/mA

-2

-4

-3

1\begin{ circuitikz }[ scale =1.2, american]\draw

2(0,2) to[ I=1<\ milli \ampere>] (2,2)

3to[R, l_=2<\kilo\ohm>, *−*] (0,0)

4to[R, l_=2<\kilo\ohm>] (2,0)

5to[V, v_=2<\volt>] (2,2)

6to[ cspst , l=$t_0$] (4,2) −− (4,1.5)

7to [generic, i=$i _1$, v=$v_1$] (4,−.5) −− (4,−1.5)

8(0,2) −− (0,−1.5) to[V, v_=4<\volt>] (2,−1.5)

9to [R, l=1<\kilo\ohm>] (4,−1.5);

11 \begin{scope}[ xshift =6.5cm, yshift =.5cm]

12 \draw [−>] (−2,0) −− (2.5,0) node[anchor=west] {$v_1/\volt$};

13 \draw [−>] (0,−2) −− (0,2) node[anchor=west] {$i_1/\SI {}{\ milli \ampere}$} ;

14 \draw (−1,0) node[anchor=north] {−2} (1,0) node[anchor=south] {2}

15 (0,1) node[anchor=west] {4} (0,−1) node[anchor=east] {−4}

16 (2,0) node[anchor=north west] {4}

17 (−1.5,0) node[anchor=south east] {−3};

18 \draw [thick] (−2,−1) −− (−1,1) −− (1,−1) −− (2,0) −− (2.5,.5);

19 \draw [dotted] (−1,1) −− (−1,0) (1,−1) −− (1,0)

20 (−1,1) −− (0,1) (1,−1) −− (0,−1);

21 \end{scope}

22 \end{circuitikz }

9 Revision history

version 0.3.0 (20121229)

1. fixed gate node for a few transistors

2. added mixer

3. added fully differential op amp (by Kristofer M. Monisit)

now general settings for the drawing of voltage can be overridden for

specific components

made arrows more homogeneous (either the current/voltage one, or

latex’ by pgf)

6. added the single battery cell

7. added fuse and asymmetric fuse

8. added toggle switch

9. added varistor, photoresistor, thermocouple, push button

10. added thermistor, thermistor ptc, thermistor ptc

11. fixed misalignment of voltage label in vertical bipoles with names

12. added isfet

13.

added noiseless, protective, chassis, signal and reference grounds (Luigi

Luigi «Liverpool»)

version 0.2.4 (20110911).

1. added square voltage source (contributed by Alistair Kwan)

2. added buffer and plain amplifier (contributed by Danilo Piazzalunga)

3. added squid and barrier (contributed by Cor Molenaar)

4. added antenna and transmission line symbols contributed by Leonardo

Azzinnari

added the changeover switch spdt (suggestion of Fabio Maria Antoniali)

6. rename of context.tex and context.pdf (thanks to Karl Berry)

7. updated the email address

in documentation, fixed wrong (non-standard) labelling of the axis in an

example (thanks to prof. Claudio Beccaria)

9. fixed scaling inconsistencies in quadrupoles

10. fixed division by zero error on certain vertical paths

11. introduced options straighlabels, rotatelabels, smartlabels

version 0.2.3 (20091118).

1. fixed compatibility problem with label option from tikz

2. Fixed resizing problem for shape ground

3. Variable capacitor

4. polarized capacitor

5. ConTeXt support (read the manual!)

nfet, nigfete, nigfetd, pfet, pigfete, pigfetd (contribution of Clemens

Helfmeier and Theodor Borsche)

7. njfet, pjfet (contribution of Danilo Piazzalunga)

8. pigbt, nigbt

backward incompatibility potentiometer is now the standard resistor-with-

arrow-in-the-middle; the old potentiometer is now known as variable

resistor (or vR), similarly to variable inductor and variable capacitor

10. triac, thyristor, memristor

11. new property ”name” for bipoles

12. fixed voltage problem for batteries in american voltage mode

13. european logic gates

14.

backward incompatibility new american standard inductor. Old american

inductor now called ”cute inductor”

15.

backward incompatibility transformer now linked with the chosen type of

inductor, and version with core, too. Similarly for variable inductor

16.

backward incompatibility styles for selecting shape variants now end are

in the plural to avoid conflict with paths

17. new placing option for some tripoles (mostly transistors)

18. mirror path style

version 0.2.2 (20090520).

1. Added the shape for lamps.

Added options

europeanresistor

europeaninductor

americanresistor

and americaninductor, with corresponding styles.

3. Fixed

: error in transistor arrow positioning and direction under negative

xscale and yscale.

version 0.2.1 (20090503).

1. Op-amps added.

2. Added options arrowmos and noarrowmos.

version 0.2 First public release on CTAN (20090417).

1. Backward incompatibility

: labels ending with

angle are not parsed for

positioning anymore.

2. Full use of TikZ keyval features.

White background is not filled anymore: now the network can be drawn

on a background picture as well.

Several new components added (logical ports, transistors, double bipoles,

…).

5. Color support.

6. Integration with siunitx.

7. Voltage, american style.

8. Better code, perhaps. General cleanup at the very least.

version 0.1 First public release (2007).

Index of the components

afuse, 10

ageneric, 9

american and port, 21

american controlled current source,

american controlled voltage source,

american current source, 11

american inductor, see L

american nand port, 22

american nor port, 22

american not port, 22

american or port, 21

american potentiometer, see pR

american resistor, see R

american variable resistor, see vR

american voltage source, 11

american xnor port, 22

american xor port, 22

ammeter, 8

antenna, 7

asymmetric fuse, see afuse

barrier, 13

battery, 11

battery1, 11

buffer, 24

C, see capacitor

capacitor, 13

cground, 7

circ, 24

cisourcesin, see controlled sinusoidal

current source

closing switch, 15

controlled isourcesin, see controlled

sinusoidal current source

controlled sinusoidal current source,

controlled sinusoidal voltage source,

controlled vsourcesin, see controlled

sinusoidal voltage source

csI, see controlled sinusoidal current

source

cspst, see closing switch

csV, see controlled sinusoidal voltage

source

currarrow, 24

cute inductor, see L

cvsourcesin, see controlled sinusoidal

voltage source

D*, see full diode

Do, see empty diode

empty diode, 12

empty led, 12

empty photodiode, 12

empty Schottky diode, 12

empty tunnel diode, 12

empty varcap, 12

empty Zener diode, 12

european and port, 22

european controlled current source,

european controlled voltage source,

european current source, 11

european inductor, see L

european nand port, 22

european nor port, 23

european not port, 22

european or port, 22

european potentiometer, see pR

european resistor, see R

european variable resistor, see vR

european voltage source, 11

european xnor port, 23

european xor port, 23

fd op amp, 23

full diode, 12

full led, 13

full photodiode, 13

full Schottky diode, 12

full tunnel diode, 13

full varcap, 13

full Zener diode, 12

fullgeneric, 9

fuse, 10

generic, 8

ground, 7

gyrator, 21

isfet, 19

isourcesin, see sinusoidal current

source

L, 14

lamp, 8

leD*, see full led

leDo, see empty led

memristor, 9

mixer, 20

Mr, see memristor

nfet, 18

nground, 7

nigbt, 17

nigfetd, 18

nigfete, 18

njfet, 19

nmos, 17

npn, 17

ocirc, 24

op amp, 23

open, 8

opening switch, 15

ospst, see opening switch

pC, see polar capacitor

pD*, see full photodiode

pDo, see empty photodiode

pfet, 18

pground, 7

photoresistor, see phR

phR, 10

pigbt, 17

pigfetd, 19

pigfete, 18

pjfet, 19

plain amp, 24

pmos, 17, 18

pnp, 17

polar capacitor, 13

pR, 9, 10

push button, 15

R, 9

rground, 7

rxantenna, 7

sD*, see full Schottky diode

sDo, see empty Schottky diode

sground, 7

short, 8

sI, see sinusoidal current source

sinusoidal current source, 15

sinusoidal voltage source, 15

spdt, 19

square voltage source, 15

squid, 13

sqV, see square voltage source

sV, see sinusoidal voltage source

tD*, see full tunnel diode

tDo, see empty tunnel diode

tfullgeneric, 9

tgeneric, 8

thermistor, see thR

thermistor ntc, see thRn

thermistor ptc, see thRp

thermocouple, 10

thR, 10

thRn, 10

thRp, 10

thyristor, 20

TL, 14

tline, see TL

tlinestub, 8

toggle switch, 19

Tr, see triac

transformer, 20

transformer core, 21

transmission line, see TL

triac, 20

txantenna, 8

Ty, see thyristor

variable american inductor, see vL

variable capacitor, 14

variable cute inductor, see vL

variable european inductor, see vL

varistor, 10

vC, see variable capacitor

VC*, see full varcap

VCo, see empty varcap

vL, 14

voltmeter, 8

vR, 9, 10

vsourcesin, see sinusoidal voltage

source

vsourcesquare, see square voltage

source

zD*, see full Zener diode

zDo, see empty Zener diode

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