projects / unix-history / blame
| Commit | Line | Data |
|---|---|---|
| 48baa1c3 C |
1 | |
| 2 | You can also make equations that are ________\b\b\b\b\b\b\b\bindented a fixed amount from | |
| 3 | the left margin, with the command | |
| 4 | .EQ I | |
| 5 | Again, if there is an equation number, it follows the I. | |
| 6 | ||
| 7 | Convert all the equations in "Example" to indented ones. | |
| 8 | (Naturally I've changed it.) | |
| 9 | You can do this with a single editor command. | |
| 10 | ||
| 11 | Print "Example" with neqn and nroff -ms, | |
| 12 | then type "ready". | |
| 13 | #once #create Ref | |
| 14 | .LP | |
| 15 | EQUIVALENCES OF ONE SORT AND ANOTHER | |
| 16 | .LP | |
| 17 | .EQ I (2.01) | |
| 18 | bold x sup { n alpha } (t) ~->~ bold x sup alpha ( bold X ,t). | |
| 19 | .EN | |
| 20 | .sp | |
| 21 | .EQ I (2.02) | |
| 22 | sum from n F( bold x sup { n alpha } (t)) | |
| 23 | ~->~ 1 over OMEGA INT F( bold x sup alpha ( bold X ,t))d bold \|X | |
| 24 | .EN | |
| 25 | .EQ I (2.03) | |
| 26 | bold x ( bold X ,t) ~==~ | |
| 27 | sum from { alpha =1} to N | |
| 28 | rho sup alpha over rho sup 0 bold x sup alpha ( bold X ,t) | |
| 29 | .EN | |
| 30 | .EQ I (2.08) | |
| 31 | sum from {alpha =1} to N | |
| 32 | U sup { mu alpha } V sup { mu alpha } ~=~ delta sup { mu nu } | |
| 33 | .EN | |
| 34 | .EQ I (2.06) | |
| 35 | bold y sup { T mu } ( bold X ,t) | |
| 36 | ~==~ sum from {alpha =1} to N | |
| 37 | U sup { mu alpha } | |
| 38 | bold x sup alpha | |
| 39 | ( bold X ,t) | |
| 40 | .EN | |
| 41 | .EQ I | |
| 42 | ~ partial over {partial d} | |
| 43 | ( epsilon sub 0 bold E sup T times bold B ) sub i | |
| 44 | - m sub ij,\|j ~=~ | |
| 45 | -q sup D E sub i sup T | |
| 46 | -( bold ~j sup D times bold B ) sub i | |
| 47 | .EN | |
| 48 | #once #create Example | |
| 49 | .LP | |
| 50 | EQUIVALENCES OF ONE SORT AND ANOTHER | |
| 51 | .LP | |
| 52 | .EQ (2.01) | |
| 53 | bold x sup { n alpha } (t) ~->~ bold x sup alpha ( bold X ,t). | |
| 54 | .EN | |
| 55 | .sp | |
| 56 | .EQ (2.02) | |
| 57 | sum from n F( bold x sup { n alpha } (t)) | |
| 58 | ~->~ 1 over OMEGA INT F( bold x sup alpha ( bold X ,t))d bold \|X | |
| 59 | .EN | |
| 60 | .EQ (2.03) | |
| 61 | bold x ( bold X ,t) ~==~ | |
| 62 | sum from { alpha =1} to N | |
| 63 | rho sup alpha over rho sup 0 bold x sup alpha ( bold X ,t) | |
| 64 | .EN | |
| 65 | .EQ (2.08) | |
| 66 | sum from {alpha =1} to N | |
| 67 | U sup { mu alpha } V sup { mu alpha } ~=~ delta sup { mu nu } | |
| 68 | .EN | |
| 69 | .EQ (2.06) | |
| 70 | bold y sup { T mu } ( bold X ,t) | |
| 71 | ~==~ sum from {alpha =1} to N | |
| 72 | U sup { mu alpha } | |
| 73 | bold x sup alpha | |
| 74 | ( bold X ,t) | |
| 75 | .EN | |
| 76 | .EQ | |
| 77 | ~ partial over {partial d} | |
| 78 | ( epsilon sub 0 bold E sup T times bold B ) sub i | |
| 79 | - m sub ij,\|j ~=~ | |
| 80 | -q sup D E sub i sup T | |
| 81 | -( bold ~j sup D times bold B ) sub i | |
| 82 | .EN | |
| 83 | #user | |
| 84 | #cmp Ref Example | |
| 85 | #log | |
| 86 | #next | |
| 87 | 2.1a 10 |