@Section @Tag { vpos } @Title { Vertical positioning } @Begin @PP Every equation and every object within every equation has an @I axis running through it which is used to position it vertically equations. @RawIndex { equations } equations.axis @SubIndex { axis of } axis @Index { axis of equation } with respect to nearby objects. In the Expert's Guide to Lout @Cite { $kingston1995lout.expert } this is called a @I { row mark }, but we'll stick with axis. Here are some examples with the axis shown as a dashed line: @ID { @ShowHMark @Eq { x sup 2 } ||2c @ShowHMark @Eq { non + } ||2c @ShowHMark @Eq { @ExA } } When these objects are placed adjacent to one another, their axes are merged, giving the correct vertical positioning: @ID @ShowHMark @Eq { x sup 2 + @ExA } Most of the time you do not need to think about vertical positioning, because for most objects there is just one sensible place for the axis to go, and Lout puts it there. @PP Matrices and the delimiters that enclose them are the two exceptions. Lout makes the axis of a matrix pass through its exact centre, and it shifts the axes of delimiters so that they exactly enclose the thing delimited. These choices are never disastrous, but there are other possibilities that might be better sometimes. @PP The axis of a matrix could reasonably be set to the axis of any of its rows: @ID { @ShowHMark @Eq { matrix userow { yes } { axisrow col { x sup 3 } col { y sup 3 } col { z sup 3 } row col { x sup 2 } col { y sup 2 } col { z sup 2 } row col { x } col { y } col { z } } } ||2c @ShowHMark @Eq { matrix userow { yes } { row col { x sup 3 } col { y sup 3 } col { z sup 3 } axisrow col { x sup 2 } col { y sup 2 } col { z sup 2 } row col { x } col { y } col { z } } } ||2c @ShowHMark @Eq { matrix userow { yes } { row col { x sup 3 } col { y sup 3 } col { z sup 3 } row col { x sup 2 } col { y sup 2 } col { z sup 2 } axisrow col { x } col { y } col { z } } } } Alternatively, it could be set to where Lout usually places it, through the exact centre: @ID { @ShowHMark @Eq { matrix { row col { x sup 3 } col { y sup 3 } col { z sup 3 } row col { x sup 2 } col { y sup 2 } col { z sup 2 } row col { x } col { y } col { z } } } } Delimiters could reasonably keep the axes that they naturally have (approximately through their centres, but not exactly): @ID { @ShowHMark @Eq { pmatrix userow { yes } shiftdelim { no } { @ExA } } } or they could have their axes moved in the way that Lout usually does, to the point which allows them to evenly cover the thing delimited: @ID { @ShowHMark @Eq { pmatrix userow { yes } { @ExA } } } Altogether then there are four possibilities when these two alternatives interact: @CD lines @Break @Tab @Fmta { @Col 0.5w @VShift A ! @Col ! @Col B ! @Col ! @Col C } { @Rowa A { } B { Matrix axis uses row axis } C { Matrix axis passes through centre } @Rowa @Rowa A { Delimiter keeps its axis } B { @ShowHMark @Eq { pmatrix userow {yes} shiftdelim {no } { @ExA } } } C { @ShowHMark @Eq { pmatrix userow {no } shiftdelim {no } { @ExA } } } @Rowa @Rowa A { Delimiter axis shifted } B { @ShowHMark @Eq { pmatrix userow {yes} shiftdelim {yes} { @ExA } } } C { @ShowHMark @Eq { pmatrix userow {no } shiftdelim {yes} { @ExA } } } } To supply these possibilities, the @Code "matrix" symbol and all its variants (@Code "pmatrix" etc.) have two options whose equations. @RawIndex { equations } equations.userow @SubIndex { @Code "userow" option } userow.equations @Index { @Code "userow" option (equations) } equations. @RawIndex { equations } equations.shiftdelim @SubIndex { @Code "shiftdelim" option } shiftdelim.equations @Index { @Code "shiftdelim" option (equations) } values may be {@Code "yes"} or {@Code "no"}: @ID @Code @Verbatim { matrix userow { no } shiftdelim { yes } { ... } } The @Code "userow" option determines whether the axis of the matrix will use a row axis; the default is not to, i.e. to centre the axis instead. The @Code "shiftdelim" option determines whether the axis of the delimiter will be shifted so that the delimiter evenly covers the thing delimited; the default is to do this. @PP If @Code "userow" is {@Code "yes"}, the next question is which row's axis to use to make the overall axis. If you do nothing, the first (or only) row's axis becomes the overall axis. To select some other row instead, replace the @Code "row" symbol that precedes the row by {@Code "axisrow"}: equations. @RawIndex { equations } equations.axisrow @SubIndex { @Code "axisrow" symbol } axisrow.equations @Index { @Code "axisrow" symbol (equations) } @ID @Code @Tab vmargin { 0.5vx } hmargin { 1s } @Fmta { @Col A ! @Col ! @Col B ! @Col ! @Col C ! @Col ! @Col D ! @Col } @Fmtb { @Col A ! @Col " col {" ! @Col B ! @Col "} col {" ! @Col C ! @Col "} col {" ! @Col D ! @Col "}" } { @Rowa A { "matrix userow { yes } {" &0io } @Rowb A { " row" } B { "x sup 3" } C { "y sup 3" } D { "z sup 3" } @Rowb A { " axisrow" } B { "x sup 2" } C { "y sup 2" } D { "z sup 2" } @Rowb A { " row" } B { "x" } C { "y" } D { "z" } @Rowa A { "}" } } The result of this is @ID @ShowHMark @Eq { matrix userow { yes } { row col { x sup 3 } col { y sup 3 } col { z sup 3 } axisrow col { x sup 2 } col { y sup 2 } col { z sup 2 } row col { x } col { y } col { z } } } with the axis through the second row as desired. @End @Section