#print
You can also make equations that are ________indented a fixed amount from
the left margin, with the command
.EQ I
Again, if there is an equation number, it follows the I.
Convert all the equations in "Example" to indented ones.
(Naturally I've changed it.)
You can do this with a single editor command.
Print "Example" with neqn and nroff -ms,
then type "ready".
#once #create Ref
.LP
EQUIVALENCES OF ONE SORT AND ANOTHER
.LP
.EQ I (2.01)
bold x sup { n alpha } (t) ~->~ bold x sup alpha ( bold X ,t).
.EN
.sp
.EQ I (2.02)
sum from n F( bold x sup { n alpha } (t))
~->~ 1 over OMEGA INT F( bold x sup alpha ( bold X ,t))d bold \|X
.EN
.EQ I (2.03)
bold x ( bold X ,t) ~==~
sum from { alpha =1} to N
rho sup alpha over rho sup 0 bold x sup alpha ( bold X ,t)
.EN
.EQ I (2.08)
sum from {alpha =1} to N
U sup { mu alpha } V sup { mu alpha } ~=~ delta sup { mu nu }
.EN
.EQ I (2.06)
bold y sup { T mu } ( bold X ,t)
~==~ sum from {alpha =1} to N
U sup { mu alpha }
bold x sup alpha
( bold X ,t)
.EN
.EQ I
~ partial over {partial d}
( epsilon sub 0 bold E sup T times bold B ) sub i
- m sub ij,\|j ~=~
-q sup D E sub i sup T
-( bold ~j sup D times bold B ) sub i
.EN
#once #create Example
.LP
EQUIVALENCES OF ONE SORT AND ANOTHER
.LP
.EQ (2.01)
bold x sup { n alpha } (t) ~->~ bold x sup alpha ( bold X ,t).
.EN
.sp
.EQ (2.02)
sum from n F( bold x sup { n alpha } (t))
~->~ 1 over OMEGA INT F( bold x sup alpha ( bold X ,t))d bold \|X
.EN
.EQ (2.03)
bold x ( bold X ,t) ~==~
sum from { alpha =1} to N
rho sup alpha over rho sup 0 bold x sup alpha ( bold X ,t)
.EN
.EQ (2.08)
sum from {alpha =1} to N
U sup { mu alpha } V sup { mu alpha } ~=~ delta sup { mu nu }
.EN
.EQ (2.06)
bold y sup { T mu } ( bold X ,t)
~==~ sum from {alpha =1} to N
U sup { mu alpha }
bold x sup alpha
( bold X ,t)
.EN
.EQ
~ partial over {partial d}
( epsilon sub 0 bold E sup T times bold B ) sub i
- m sub ij,\|j ~=~
-q sup D E sub i sup T
-( bold ~j sup D times bold B ) sub i
.EN
#user
#cmp Ref Example
#log
#next
2.1a 10