Testing physics.js

Automatic Bracing	Code
\( \quantity{ \frac{1}{1+\frac{1}{2}} } \)	`\quantity{ }`
\( \qty{ \frac{1}{1+\frac{1}{2}} } \)	`\qty{ }`
\( \pqty{ \frac{1}{1+\frac{1}{2}} } \)	`\pqty{ }`
\( \bqty{ \frac{1}{1+\frac{1}{2}} } \)	`\bqty{ }`
\( \vqty{ \frac{1}{1+\frac{1}{2}} } \)	`\vqty{ }`
\( \Bqty{ \frac{1}{1+\frac{1}{2}} } \)	`\Bqty{ }`
\( \absolutevalue{ \frac{1}{1+\frac{1}{2}} } \)	`\absolutevalue{ }`
\( \abs{ \frac{1}{1+\frac{1}{2}} } \)	`\abs{ }`
\( \norm{ \frac{1}{1+\frac{1}{2}} } \)	`\norm{ }`
\( \evaluated{ \frac{1}{1+\frac{1}{2}} }_1^2 \)	`\evaluated{ }_1^2`
\( \eval{ \frac{1}{1+\frac{1}{2}} }_1^2 \)	`\eval{ }_1^2`
\( \order{ \frac{x}{2} } \)	`\order{ }`
\( \commutator{A} {B} \)	`\commutator{A} {B}`
\( \comm{A} {B} \)	`\comm{A} {B}`
\( \anticommutator{A} {B} \)	`\anticommutator{A} {B}`
\( \acomm{A} {B} \)	`\acomm{A} {B}`
\( \poissonbracket{A} {B} \)	`\poissonbracket{A} {B}`
\( \pb{A} {B} \)	`\pb{A} {B}`

Vector Notation	Code
\( \vectorbold{ a } \)	`\vectorbold{ }`
\( \vb{ a } \)	`\vb{ }`
\( \vb{ \psi } \)	`\vb{ }`
\( \vb*{ a } \)	`\vb*{ }`
\( \vb*{ \psi } \)	`\vb*{ }`
\( \vectorarrow{ a } \)	`\vectorarrow{ }`
\( \va{ a } \)	`\va{ }`
\( \va{ \psi } \)	`\va{ }`
\( \va*{ a } \)	`\va*{ }`
\( \va*{ \psi } \)	`\va*{ }`
\( \vectorunit{ a } \)	`\vectorunit{ }`
\( \vu{ a } \)	`\vu{ }`
\( \vu{ \psi } \)	`\vu{ }`
\( \vu*{ a } \)	`\vu*{ }`
\( \vu*{ \psi } \)	`\vu*{ }`
\( \dotproduct \)	`\dotproduct`
\( \vdot \)	`\vdot`
\( \crossproduct \)	`\crossproduct`
\( \cross \)	`\cross`
\( \cp \)	`\cp`
\( \gradient( \psi ) \)	`\gradient( )`
\( \grad( \psi ) \)	`\grad( )`
\( \grad[ \psi ] \)	`\grad[ ]`
\( \grad{ \psi } \)	`\grad{ }`
\( \divergence( \psi ) \)	`\divergence( )`
\( \div( \psi ) \)	`\div( )`
\( \div[ \psi ] \)	`\div[ ]`
\( \div{ \psi } \)	`\div{ }`
\( \curl( \psi ) \)	`\curl( )`
\( \curl[ \psi ] \)	`\curl[ ]`
\( \curl{ \psi } \)	`\curl{ }`
\( \laplacian( \psi ) \)	`\laplacian( )`
\( \laplacian[ \psi ] \)	`\laplacian[ ]`
\( \laplacian{ \psi } \)	`\laplacian{ }`

Operators	Code
\( \sin x \)	`\sin`
\( \sin( x ) \)	`\sin( )`
\( \sin[2]( x ) \)	`\sin[2]( )`
\( \tr \rho \)	`\tr`
\( \Tr \rho \)	`\Tr`
\( \rank M \)	`\rank`
\( \erf( x ) \)	`\erf( )`
\( \Res[ f(z) ] \)	`\Res[ ]`
\( \principalvalue{ \int f(z) \dd{z} } \)	`\principalvalue{ }`
\( \pv{ \int f(z) \dd{z} } \)	`\pv{ }`
\( \PV{ \int f(z) \dd{z} } \)	`\PV{ }`
\( \Re{ \frac{1}{1+\frac{i}{2}} } \)	`\Re{ }`
\( \Im{ \frac{1}{1+\frac{i}{2}} } \)	`\Im{ }`

Quick Quad Text	Code
\( \qqtext{ some texts } \)	`\qqtext{ }`
\( \qq{ some texts } \)	`\qq{ }`
\( \qq*{ some texts } \)	`\qq*{ }`
\( \qcomma \)	`\qcomma`
\( \qc \)	`\qc`
\( \qcc \)	`\qcc`
\( \qif \)	`\qif`
\( \qthen \)	`\qthen`
\( \qelse \)	`\qelse`
\( \qotherwise \)	`\qotherwise`
\( \qunless \)	`\qunless`
\( \qgiven \)	`\qgiven`
\( \qusing \)	`\qusing`
\( \qassume \)	`\qassume`
\( \qsince \)	`\qsince`
\( \qlet \)	`\qlet`
\( \qfor \)	`\qfor`
\( \qall \)	`\qall`
\( \qeven \)	`\qeven`
\( \qodd \)	`\qodd`
\( \qinteger \)	`\qinteger`
\( \qand \)	`\qand`
\( \qor \)	`\qor`
\( \qas \)	`\qas`
\( \qin \)	`\qin`

Derivatives	Code
\( \differential{ x } \)	`\differential{ }`
\( \dd{ x } \)	`\dd{ }`
\( \dd[3] {x} \)	`\dd[3] {x}`
\( \dd( \cos\theta ) \)	`\dd( )`
\( \dv{ x } \)	`\dv{ }`
\( \derivative{ f }{x} \)	`\derivative{ }{x}`
\( \dv{ f }{x} \)	`\dv{ }{x}`
\( \dv[ n ]{f}{x} \)	`\dv[ ]{f}{x}`
\( \dv{x}( x^2+x^3 ) \)	`\dv{x}( )`
\( \dv*{ f }{x} \)	`\dv*{ }{x}`
\( \pdv{ x } \)	`\pdv{ }`
\( \partialderivative{ f }{x} \)	`\partialderivative{ }{x}`
\( \pdv{ f }{x} \)	`\pdv{ }{x}`
\( \pdv[ n ]{f}{x} \)	`\pdv[ ]{f}{x}`
\( \pdv{x}( x^2+x^3 ) \)	`\pdv{x}( )`
\( \pdv{ f }{x}{y} \)	`\pdv{ }{x}{y}`
\( \variation{ F[g(x)] } \)	`\variation{ }`
\( \var{ F[g(x)] } \)	`\var{ }`
\( \var( E-TS ) \)	`\var( )`
\( \fdv{ g } \)	`\fdv{ }`
\( \functionalderivative{ F }{g} \)	`\functionalderivative{ }{g}`
\( \fdv{ F }{g} \)	`\fdv{ }{g}`
\( \fdv{V}( E-TS ) \)	`\fdv{V}( )`
\( \fdv*{ F }{x} \)	`\fdv*{ }{x}`

Dirac Bracket Notation	Code
\( \ket{ \frac{\psi + \phi}{2} } \)	`\ket{ }`
\( \ket*{ \frac{\psi + \phi}{2} } \)	`\ket*{ }`
\( \bra{ \frac{\psi + \phi}{2} } \)	`\bra{ }`
\( \bra*{ \frac{\psi + \phi}{2} } \)	`\bra*{ }`
\( \innerproduct{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\innerproduct{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \braket{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\braket{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \braket*{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\braket*{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \braket{ \frac{\psi + \phi}{2} } \)	`\braket{ }`
\( \outerproduct{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\outerproduct{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \dyad{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\dyad{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \ketbra{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\ketbra{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \op{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\op{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \ketbra*{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}} \)	`\ketbra*{\frac{\psi + \phi}{2}}{\frac{\psi + \phi}{2}}`
\( \ketbra{ \frac{\psi + \phi}{2} } \)	`\ketbra{ }`
\( \expectationvalue{ \frac{\psi + \phi}{2} } \)	`\expectationvalue{ }`
\( \expval{ \frac{\psi + \phi}{2} } \)	`\expval{ }`
\( \ev{ \frac{\psi + \phi}{2} } \)	`\ev{ }`
\( \ev{ \frac{A+B}{2} }{\psi} \)	`\ev{ }{\psi}`
\( \ev*{ \frac{\psi + \phi}{2} } \)	`\ev*{ }`
\( \ev**{ \frac{\psi + \phi}{2} } \)	`\ev**{ }`
\( \matrixelement{m}{ \frac{A+B}{2} }{n} \)	`\matrixelement{m}{ }{n}`
\( \matrixel{m}{ \frac{A+B}{2} }{n} \)	`\matrixel{m}{ }{n}`
\( \mel{m}{ \frac{A+B}{2} }{n} \)	`\mel{m}{ }{n}`
\( \mel*{m}{ \frac{A+B}{2} }{n} \)	`\mel*{m}{ }{n}`
\( \mel**{m}{ \frac{A+B}{2} }{n} \)	`\mel**{m}{ }{n}`