LMD 40 Pre-emptionData Chart Intersection Name Oper Manual...LMD 40 Pre-emptionData Chart...
Transcript of LMD 40 Pre-emptionData Chart Intersection Name Oper Manual...LMD 40 Pre-emptionData Chart...
• LMD 40 Pre-emption Data Chart Intersection Name:
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pRE-EMPTION SEQUENCE CODES (Pre-empt sequence chart on back)
PE STEP II = Sequence Step # 1-99
INTERVAL CODES
o = NOP (can be used with JUMP or VECTOR instructions)
101·832 = Display specified interval (1st digit = signal plan)
841 = Clear HI PE Call 1 851 = Clear Lo PE Call 1
842= Clear HI PE Call 2 852 = Clear lo PE Call 2
843= Clear HI PE Call 3 853 = Clear lo PE Call 3
844 = Clear Hi PE Call 4 854 = Clear lo PE Can 4
845 = Clear Hi PE Call 5 855 = Clear lo PE Call 5
860 = Clear All Calls
900-999 = Pre-empt Exit Re-sync. Second 2 digits 0-99%. Used to
sync Pre-empt to cycle timer. If cycle timer is less than specified percent,
hold in last displayed interval until cycle timer '= % value, then
execute JUMP Instruction. If the cycle timer Is greater than % value,
Immediately go to next step.
98 = RETURN to normal operation at end Of current interval, only clear
calls that initiated that PE transfer.
99 '= RETURN to normal unconditional at end 01 current interval (clear all
PE calls).
MIN = Minimum time 01 interval. If vector instructions ate used with
higher priority PE, vector will walt for MIN time.
Normal (MAX) time of interval If no higher priority vectors take
place.
HOLD ON INPUT, 0-10; 0 = No hold, 1-5 = Hi priority pre-empts,
6-10 = lo priorltypre-empts. If 1-10, will hold until input goes
away, or vector override, or override/fail.
JMP = Jump Instructions
001-099 = Jump unconditionally to specified step
101-199 = Jump on Hi PE Call 1 to step #1-99
201-299 '= Jump on Hi PE Call2to step #1-99
301·399 = Jump on HI PE Call3to step #1·99
401-499 = Jump on Hi PE Call 4 to step #1-99
501-599 = Jump on Hi PE Call 5 to step #1-99
601-699 = Jump on lo PE Call 1 to step #1·99
701-799 = Jump on lo PE Call 2 to step #1-99
801-899 = Jump on Lo PE Call3to step #1·99
901-999 = Jump on lo PE Call4to step #1-99
.01-.99 = Jump on lo PE Call 5 to step #1-99
V1·S'" Priority vectors 0-99. Jump to Indicated step if higher priority PE
becomes active (after MIN time). Only jump if PE is higher priority
than active PE and there is a vand vector step. If more than 1
active, highest priority PE takes precedence.
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PRE-EMPTION SET-UP PARAMETERS
I
HI
EXIT FLASH
FAIL TIME
PRIORITY
PRE·EMPT IN
OVERRIDE TIME
MINIMUM BE·SERVICE
DELAY BEFORE PRE·EMPT
'LAST X" SECONDS (HOLD
lOW PRIORITY PRE·EMPTS DURING MINIMUM RE-SERVICE
HIGH PRIORITY PRE-EMPTS DURING MINIMUM RE-SERVlCE
LAST X SECONDS =0-255 Seconds; Specifies the "Last X· seconds of the
delay before pre-empt, during which the LMD40 will nolterminate intervals
designated as 'PE DELAY HOLD" Intervals (related to that PEl. Preventsstarting a new Interval Just before pre-empt actually occurs.
PRE-EMPTION SET-UP COpES
EXIT FLASH = 0 or 1; 0 = PE sequence does not override remote flash.
= unit will exit remote flash into signal plan flash exit Interval, then pre
empt from there. Low priority PE's cannot override flash.
MINIMUM BE·SERVICE = 0-99 Minutes; Specifies the number of
minutes, after a pre-empt, before a new pre-empt is allowed (see PE's AL·
LOWED below)
DELAY BEFORE PE = 0-255 Seconds
HOI =FAIL TIME = 0-255 Minutes; 'Specifies a fail time beginning with activation
of the Input. If the Input remains active and the timer times out, the pre-
empt input will be canceled and pre-emption will be overridden. The unit
will return to normal, then cycle to remote Ilash. De-activation of input
resets timer.
PRIORITY = 1-5; Sets priority of pre-empts, where 1 is the highest, 5is
the lowest. Equal priority; First come, first serve. Note: low priority PE's are
all priority 6 ~ower than any high priority PEl and are not programmable.
PE'. DURING MIN RE·SERVICE "" 0-255 Pre-empts; Specifies the num
ber of pre-empts allowed within re-service period before MINIMUM RE·SER
VICE restrictions applied. (e.g. 2 '= 2 pre-empts could occur within the
re·service period, after some initial pre-empt. Thus, use "2' if you wish toallow 3 pre-empts in a row, "3' for 4 in a row, etc..
OVERRIDE TIME = 0-255 Seconds; Specifies an override time beginning
with activation of the Input. If the input remains active and the timer times
out, the pre-empt Input will be canceled and pre-emption will be overrid
den. The unit will retIJrn to normal or other PE. De-activation of input resets MAX =
timer.
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PRE-EMPTION SEQUENCE STEPS
STEP # INT MIN MAX HOI JMP V1 V2 V3 V4 V5 COMMENTS
I 103 1 rid PED CLf=A~
,:/ 108 JPI TO 83 .;/.:/0 JPdl TO dO
4 3.;/3 JP3 To d35 608 JP(, (LPE/) To 8
" 111 .JP7 (LPE.:t) To /7
7 8:13 JP8 (LPE3) To ,,73
8 1.;18 4 {If:? )lE,- (I+.:t) G
9 1.R9 I (lJ.;/ RED, (/ +.;l) G
10 114 JPI 14
1/ 130 10 .J/o ., /4- d,;I 63 P€~ (L PI: t) HOL1> IAiT
/.;1 1:10 4 (lJ1 VE,-
13 9'7 RET To NORMAL
14 1.30 10 ,,;(0 I P€I HOLl> lAir
/.5 1.:10 4 ~I YEL
16 99 RET To NORMAL
17 1.31 10 .:to 1 8 .;10 .:13 PE7 (LPE:I)J.!OCD INr
18 104 4- $:1 YEL
19 99 RET TO NORMI'IL
.;/0 131 10 .;/0 ;< 8 PE.;/ HOLT) lAir
.J/I 104 4 {If':/ )lEL
.:I.:? 99 " RH 70 NORMAL-
':<3 104- 4 0.:1.5 ¢:I YEL JNlP 70.:15
.;/4- lOS .;/ ALL RED REVERT TIME
.J/S 105 I 1/4 ALL R€D, Jpl To 14
6<6 .;/,:/0 J P':;' TO .20
.;/7 334- JP3 TO ..34
.:18 MI .JP~ (LPEI) TO II
.:19 711 JP7 (LPE;;') TO /130 831 JP8 (LPE.3) TO 31
31 13:1 10 ';;0 8 49 49 34- PEB (LPE3) I-/OLD lAir
3.;1 11.:1 4 ¢3 YEL
33 qq RET To NoRNJAL.
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LMD40 Signal Plan Chart Intersection Name" Signal Plan Number· 1
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LMD40 Per Unit Programming Data Chart
Intersection Name:_--->..3"'¢"'--_T<LeS.£e _
PER UNIT DATA
ADVANCED FLASH RATE 0 0=60,1=120,2=150,3=180
NUMBER OF INTERVALS .,<4 0-32 INTERVALS
50 or 60 HERTZ '" 6=60,5=50
MINIMUM FLASH 4- o. 255 SECONDS
PER SIGNAL PlAN DATA (specify designated interval 1-32)
~SIGNAL PLAN 1 2 3 4 5 6 7 5
FLASH EXIT f f I f I I I IDWELL ..? dl 01 dl dl ,;j -'l ..l
INITIAlIZE I I I I I f f ISPECIAl SIGNAl PLAN TRANSFER CODES (0 = DON'T CARE, 1= SELECTIVE ACTUATIONS)
Sig. ON ACTUATIONS AND NOT ON ACTUATIONSCod. Plan
1 2 3 4 5 6 7 6 9 10 1 2 3 4 5 6 7 6 9 10
90 .3 X X Ix91 4- /><. >< X92 5 X93 to ><94 1 ><95
96
97
98
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.'SPECIAL SIGNAL PLAN XFER ACTUATION CODE
These special codes can be assigned in the signal plan transfer blocks to allow transfer based on user defined data. Foreach cexte to be used (90-99), specify the signal plan as well as the "on" and "not on" actuations by placing a "1" under thedesired actuations. Place O's If it doesn't matter what the actuation is for the indicated logic.
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•••••••••••••••••••••LMD40 Timing Plan Chart (continued on back)
s¢ TlFeIntersection Name:
25
CYCLE SPLIT 2
LENGTH SPLIT 3
.:lcL SPLIT 4
CYCLE SPLIT 2
L~H ::~:~~1 10.s.3 -3 .3 I 4 1 ,:l ,;l .:1_.2 4
261.~LI 28 :_-29J3()I,~,1:1 32
CYCLE SPLIT 2LENGTH SPUT 3
!KL.. SPLIT 4
iT8l,3 .3 <fl.:lCYCLE SPLIT 2
LENGTH SPLIT 3100-~ SPLIT 4
ICYCLE SPLIT 2
LENGTH ,-"S"PL",IT!-3"-j_+-f--+-+---1-+-f--+-+--1f-+-+---+-+-f--+-+---+-+-f--+-+---+-+-f--+-+---+-+-f-+---iFElEE r$PUT4 --
CYCLE 6 FSPLIT 1
CYCLE SPLIT 2LENGTH SPLIT 3
SPLIT 4
CYCLE 7 I SPUn
CYCLE SPUT 2LENGTH SPLIT 3
SPLIT 4
CYCLE 8 ( SPLlT1
CYCLE I -"""'-"-+---j-+-t--+-+-f-+-+--t-+~f--+-+--t-+-t---+-+--t-+-t---+-+---j-+-t---+-+---j-+-f---1LENGTH IP"'"-"-+---+-+---+-+---+--H-+-+-+---+-+---+--H--+-+---+--+-+-H-+-+-+---+-+---+--H-+---1
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o= RESYNC 2 = SHORTWAY1 = DWELL 3 = INTERRUPTER
SIGNAL PLAN TO SPLIT LINKING *
2131415161718o 0
0= NO LINKING, 1-4=UNK SPUT 1-4 TO BIG PLAN
OFFSET SEEKING MODE
DETECTOR FAIL SAMPLE PERIOD (0-255 MINUTES)
ILOCAl DETECTOR 1 2 3 4 5 6 7 8 9 10
L FAIL RECALL 0 0 0 0 0 0 0 0 NlA N/A ON/OFF
MINIMUM 0 0 0 0 0 0 0 0 N/A NlA (0-999)
MAXIMUM 0 0 0 0 0 0 0 0 NlA NlA (0-999)
,',',',','•. ",',W,',,,,",','"
SYSTEM DET 1 2 3 4 5 6 7
MINIMUMON/OFF, 9=CLOCK, 10=INTERCONNECT, 11 =COMM, 12=AUTO
1-8= MANUAl, 13ALL OTHER MODES OR'D
ON/OFF, 9= CLOCK, 10= INTERCONNECT, 11 =COMM, 12=AUTO
1-8= MAN, 9=CLOCK, 10= INTERCONNECT, 11 =CQMM, 12=AUTO
1-8=MAN, 9=CLOCK, 10= INTERCONNECT, 11 =COMM, 12=AUTO
1-9=MAN, 9=CLOCK, 10= INTERCONNECT, 11 =COMM, 12=AUTO
MEMORY PROGRAMMING (PE's 6-10 are low priority)
..312 3 4 5 6 7 8 9 10
.B ~ ,;? 2 21 (0-3)
II I I I I I I (1 or 2)
0= INHIBIT, 1- MEMORY OFF, 2 - MEMORY ON, 3'" RECALL
DETECTOR DELAY
2 3 4 5 6 7 8 9 10
01 0 0 0 0 0 0 0 N/A N/A IrQ-255 s&cs'
COORDINATION SELECT MODES
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OFFSETS and MAX DWELL
CYCLE I OFFSET 1 OFFSET 2 OFFSET 3 OFFSET 4 I OFFSET 5 IMAX DWELd SIGNAL PLAN
0 0 0 02 0 0 0 03 0 0 0 04 0 0 0 05 0 0 0 06 0 0 0 07 0 0 0 08 0 0 0
SPLIT I 9CYCLE I 9
FLASH
OFFSET I 9
SYSTEM
SIGPLAN 1/8
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PRE-EMPTION SEQUENCE COPES (Pre-empt sequence chart on back)
PE STEP if; = Sequence Step # 1-99
INTERVAL CODES
o= Nap (can be used with JUMP or VECTOR Instructions)
101-832 = Display specified IntelVal (1st digit = signal plan)
841 = Clear Hi PE Call 1 851 = Clear Lo PE Call 1
842= Clear Hi PE Gall 2 852 = Clear Lo PE Call 2
843 = Clear Hi PE Can 3 853 = Clear Lo PE Call 3
844 = Clear Hi PE Call 4 B54 = Clear Lo PE Call 4
845 = Clear Hi PE Call 5 855 = Clear Lo PE Call 5
860 = Clear All Calls
900-999 .. Pre-empt Exit Re-sync. Second 2 digits 0-99%. Used to
sync Pre-empt to cycle timer. If cycle timer is less than specified percent,
hold in last displayed intelVal until cycle timer = % value, then
execute JUMP instruction. If the cycle timer Is greater than % value,
immediately go to next step.
98 = RETURN to normal operation at end of current intelVal, only clear
calls that Initiated that PE transfer.
99 = RETURN 10 normal unconditional at end of currenllnlelVal (clear all
PE calls).
MIN = Minimum time of IntelVat If vector instructions are used with
higher priority PE, vector will wait for MIN time.
Normal (MAX) time of intelVal if no higher priority vectors take
place.
HOLD ON INPUT, Q.10; 0= No hold, 1-5 = Hi priority pre-empls,
6-10 = Lo priority pre-empts. If 1-10, will hold until input goes
away, or vector override, or overridelfail.
JMP = Jump Instructions001-Q99 = Jump unconditionally to specified step
101-199 .. Jump on Hi PE Gall 1 to step #1-99
201-299 .. Jump on HI PE Call2to step #1-99
301·399 = Jump on Hi PE Call3to step #1·99
401·499 = Jump on Hi PE Call4to step #1·99
501·599 = Jump on HI PE Call 5 to step #1-99
601-699 = Jump on Lo PE Call lto Step #1-99
701·799 = Jump on Lo PE Call2to step #1·99
801-899 = Jump on Lo PE Call 3 to step #1·99
901-999 = Jump on Lo PE Call 4 to step #1-99
.01·.99 = Jump on Lo PE Call 5 to step #1-99
V'-5 = Priority vectors Q.99. Jump to Indicated step if higher priority PE
becomes active (after MIN time). Only jump if PE is higher priority
than active PE and there is a valid vector step. If more than 1
active, highest priority PE takes precedence.
Intersection Name"LMD 40 Pre-emptIon Data Chart
pRE-EMPTION SET-UP COPES
PRE-EMPTION SET-UP PARAMETERS
PRE-EMPT IN H1 H2 H3 H. H. L1 L2 L3 L4 1.5
DELAY BEFORE PRE-EMPT 0'LAST X" SECONDS (HOLD) 0
MINIMUM RE-SERVICE '"OVERRIDE TIME n
FAIL TIME
PRIORITY I .;( .3 4 5 • 6 6 6 6
EXIT FLASH 0 0 0 0 0 0 0 0 0
--HIGH PRIORITY PRE-EMPTS DURING MINIMUM RE·SERVICE
LOW PRIORITY PRE·EMPTS DURING MINIMUM RE-SERVICE
DELAY BEFORE PE = Q.255 Seconds
HOI =FAIL TIME = 0-255 Minutes; Specifies a·fall time beginning with activatIon
of the input. If the input remains active and the timer times out, the pre-
empt Input will be canceled and pre-emption will be overridden. The unit
will return tp normal, then cycle to remote flash. De·activation of Input
resets timer.
LAST X SECONPS =0-255 Seconds; Specifies the "Last X' seconds of the
delay before pre-empt, during which the LMD40 will not terminate intelVals
designated as 'PE DELAY HOLO"intelVals (related to that PE). Prevents
starting a new intelVal Just before pre-empt actl.lally occurs.
PE'. DURING MIN RE-SERVICE = Q.255 Pre-empts; Specifies the num
ber of pre-empts allowed within re·selVice period before MINIMUM RE-SER
VICE restrictions applied. (e.g. 2 = 2 pre-empts could occur within the
re-servlce period, after some Initial pre-empt. Thus, use '2" if you wish to
allow 3 pre-empts in a row, "3' for 4in a row, etc..
PRIORITY = 1·5; Sets priority of pre-empts, where 1 is the highest, 5 is
the lowest. Equal priority; First come, first serve. Note: low priority PE's are
all priority 6 (lower than any high priority PEl and are not programmable.
EXIT FLASH = 0 or 1; 0 = PE sequence does not overrIde remote flash. 1
= unit will exit remote flash Into signal plan flash exit IntelVal, then pre
empt from Ihere. Low priority PE's cannot override flash.
OVERRIPE TIME = Q.255 Seconds; Specifies an override time beginning
with activation of the Input. If the input remains active and the timer times
out, the pre-empt input will be canceled and pre-emption will be overrid-
den. The unit will return to normal or other PE. De-activation of input resets MAX =
timer.
MINIMUM RE-SERVICE = 0-99 Minutes; Specifies the number of
minutas, after a pre-empt, before a new pre-empt is allowed (see PE's AL
LOWED below)
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PRE·EMPTION SEQUENCE STEPS
STEP # INT MIN MAX HOI JMP V1 V2 V3 V. V5 COMMENTS
/ /.:14 7 099 1I.:l FDVJ QO To 99.;< 11.3 PE' BRANCH€S ~"".~.,J-3 :<8(
<1 384S 013h 11?1
'1 8R48 /31 10 dO 7 95 1;/ 95 LP€ it.;? Ho'-l> (;?, .:11"3)
9 1018 <1 IIJ;) Y€L, dl1"3 eRN
10 105 .;< (If;) R€I>
II 99 R€7 ;0 NOR""1A c...
I,;{ 131 10 0'(0 .:l 009 95 HPEtr.;< HexI>, JNlP To 9
13 3R8 4- 12J~, 01 /-.3 Y€L
14 3,;1.7 .:l 119 ¢Pl, .;{ 1"3 R€i» JPI 70 19
15 130 /0 e?o ., /9 9& 9~ LPE "I 1I0Ll> 0,1-.2)
Ih 1;;J9 4 ¢I V€L) f.f.:? eRN
17 1':<,:< <:? ¢I R€D, 1/,;( (:}RN
18 99 RET To NoRM~L
19 /30 10 :?o I O/f", HPE ill HOL?> , .iMP 70 II,
~o 1.:It, P" f3RJ'lNCHcS ( f"t~"fl c<,. )
';;>1 .:I3R
:<;1 .' 3Rt.013 t..:< {p
e?4- 138.:15 &It,.;/(, 1~7 4- (lJ.:l/-3 V€L
;(1 1~/o .:l 1/9 ~h,- R€D, JPI To 19
;J.B c<1';!' ;:1<, R€D P€ BRANcHEs
,,9 133'130 M5J( 1011
..3;; 83333 /3':< 10 010 8 91 97 31 LP€ it3 /-IoLD (¢3, !f3)
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PRE-EMPTION seQUENCE STEPS
STEP # INT MIN MAX HOI JMP V1 V2 V3 v, V5 COMMENTS
.34 .:I3;{ 4 ¢a )le,- , /f3 qRN
35 1/4 .:? ¢3 RED, If:> qRN
3" 99 RiFt' To NoR""
37 1.3;>, 10 '£/0 ..3 034 97 97 f/P€;3 Hot"D, J"",P t'034
.31'1 106 .3 .;/1.;< ¢..:/ Rl?D J JP';) To 1~
-39 008 J""P 70 840 14t>
( FR.,."p€ 8R~"'CHiF!:> 3,,>,3,,+36;
41 .:154
4;< 34143 641.>44 76446 84741.> 5.;<Fl 4 0.:17
)'l JMP¢3, .;If 3, Id tL, To.:l7
47 5:7.7 4 .;11-.3 Y"'L, ¢3, /fB 6RN
48 6;11., .:I 331 ,;(1-.3 !?l?Z> Jp.3 To-31
49 033 JNJP 1'0.33 (LPe IT.3)
50 56 5(" 57 p€ &~NCNl?S (3 FJ,':1)Q.R)51 Mlo5,;1, 7510
53 85764 0,3.;/ 4 (1.3 Ye'- 1f3 Rl?l>
55 0,31 4 5 008 1':< (/J.a REP, 113 YEL, V.;l TO I.:?
510 ;1.;19 4 0..1 /f3 JI~'-, JMP To .:11
67 114 -.3 331 Rl?l> REV JP.:J 1'0.3'1
58 033 JNlP 1'0.38 (LPF ;3)
69 165 PE BR"AJCHl!!> (/'2R~':J a)60 ;11..8
01 34>9
0.:1 &.4>.5,,;.a 74>8
"4 81..9
65 :?.:J8 4 1+3 )ltfL, ¢ I) 1f.;J. qRA/
"6 ~.:I7 .:I 1/9 /f3 RED, JP/ To /9
PRE-EMPTION SEQUENCE STEPS
STEP # INT MIN MAX HOI JMP V, V2 V3 V, V5 COMMENTS
61 015 JMP To /5 (LP€ Itl)
68 33.;l 4 0:/'1 ¢I, 1,.;/, '-3(,,< JMP To.:l1
~9 330 4 111,1,.;/ rIFL 1,3 eRN
10 3,;/9 .>:I 331 111, I,.;; Ru>, JP8 70.iJ1
11 033 J/V1P 7033 (lP€ It3)
1;/ 331 4 0,27 II-::l Y€'L I .J""p TO::l1
7'3 80 1c:1 7;1 (FRO'" )PtE BRnNCHIF:' I ,,~c.,.
74 ~O
7'5 71<71
11, 81,;1.
17 694
78 790
79 89;/
80 1.:1:/ ..3 4 015 19 411, 1,.3R>t'oyi TD 19 M 'FNo
JN7P To 15
81 43;/ 4 f_::I Yt?'L, dI, ';1.3 t$RN
8.:1 431 c:I c:l1.:l If.;( RED, Jp.;? To /.;<
83 008 JNlP To 8 (LPIF #.;1)
84 430 4 (/J,;;, If.;) Y€L
85 4.::l9 ,f{ 331 ALL RE/) ,.JP3 70 3'1
81, 033 JIVJP To .33 (LP€ #".3)
81 dl01 1 a3 P€D C<J'(~I<OHI "'~88 94 90 9.>:1 P€ f3R'IJoICHE!S ( .. !J'~"l>W
89 077 Jff1P To 1'1
90 <'30 4 <b.B YIFL, .;:; 1-3 qRN
91 <'#19 c:I 3 1::1¢ V.;l: 70 J~ oR IJ:
008 .3 REDJ NOr".? ·.I"'IP ro8
"I:; 6~8 4 0<~.3 tEL
6:l'7 .3 37 V.3 ~'!! OR::"Nor 03,93 .:I 033 ':;,...3 Ret>, TO
94 .:113 4 0:l1 3, ';;'3 Y<'L, JMP 1"0.;2'1
95 53.;/ 4 0:/1 .:I a 1-.3 tEL, JIVIP To d21
qt, 531 4 0:l1 I, 1+.:1 YEL) J""P To .:11
9'1 530 4 0#11 .3 1>3, .;/,3 YE'<,JMP TD,;;r
98 5.:19 4 0:l1 :;'6 )IeL JMP To d27
99 101 5 00;/ .:1,3 ~'N£-;gN Jmp 1'0 d
•••••••••••••••••••••
•Signal Plan Number· I
NIL PoE I • ~.:I
H/e Po£..:1: {l4
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, , , , , ,,y... ,
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~4 " ~~",,",n....
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A A3 R4 R4 4 4. R4- , , RI 1n Ib~
~," .:I 1 I~ ... o ;,if) 0;0 I. 1.:1 :u 1 1 1 " ~
% "" 1'<l..Dw P"o'l "" 1 1 0 .:>0 .... 20 i. 1 j,;/ 'lJ "I "I .,1 I. 1.:1
, '" e",~"
",,"'Plan Xler 1
Minimum Tlml .
II LMD40 Signal Plan Chart Intersection Name·
••••••
••••
•
••••
•
•••
•
,
•
•••••
••1 32 DIM
Signal Plan Number' .;(
, . ,
FF F F
Intersection Name'
4587881011111411171819
"
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"",""
/>
/>w
l'J SI nal #
I ,fI <-,
.3
LMD4Q Signal Plan Chart
•••••""" ••
h Inhibll
Auto Tlmln
~
Hi P
low PE~,
PE De4a Held
Hold
'_00FlasI1 En!
I~Xla,
I~~r
II
f f jl I >/iJ(.. f f
£.1 Eo1<3 Il
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I I I£1 c.i Col.,. •••
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Minimum Tlmln
rer-1ralt1cControl •-, r-1echnologles
•
•••••••••••••••••••••
LMD40 Per Unit Programming Data Chart
Intersection Name:._---'4t,,0f"'--- _
PER UNIT DATA
ADVANCED FLASH RATE /J 0-60,1-120,2-150,3-180
NUMBER OF INTERVALS .29 0-32 INTERVAlS
50 or 60 HERTZ '0 6 - 60,5 - 50
MINIMUM FLASH 4 . 0 - 255 SECONDS
PER SIGNAL PtAN DATA (specify designated IntelVsl 1-32)
SIGNAL PLAN 1 2 3 4 5 6 7 8
•FLASH EXIT I I I I I I I /
DWELL -? -' .:l PI PI ~ .:< PIINITIALIZE I I I I I I I I
SPECIAL SIGNAL PLAN TRANSFER CODeS (0- DON'T CARE, 1- SELECTIVE ACTUATIONS)
8ig. ON ACTUATIONS AND NOT ON ACTUATIONSCod. PI,"
1 2 3 4 5 6 8 9 10 1 2 3 4 5 6 6 9 107 7
90
91
92
93
84
95
96
97
96
99
"SPECIAL SIGNAL PLAN XFER ACTUATION CODE
These special codes can be assigned in the signal plan transfer blocks to allow transfer based on user defined data. Foreach code to be used (90-99), specify the signal plan as well as the "on" and "not on" actuations by placing a "1" under thedesired actuations. Place O's if it doesn't matter what the actuation is for the indicated logic.
--J L-Trafflt:Control-fC,L Technologies
LMD40 Timing Plan Chart
Intersection Name: 40,I I
CYCLE SPUT 2LENGTH SPUT 3
!l.CL. SPUT 4
$3
(continued on back)
CYCLE SPUT 2
LENGTH L2'SP!:!L':'Teo3'--t-t--I-+-t----t-t--f--t--t---t-+-t--+-t--I-+-t--+-t--I,+-t----t-t--if-+-t---I-t--f-+-Itoo I-- SPUT4
CYCLE 3I SPLIT' I~I I ri.21 ". 1161 ,31.-3'13 I;;;> 1~ 14 7T71.31:3T.3I..:1I~ 1151.31.3~1.:11..;l141 fCYCLE SPUT 2
LENGTH SPUT 3iJQ rSp-'L"'T"".+-I-+---"I-+-I-+-I,+-I-+--'I-+-II-+-II-+-II-+-I-+-I-+-t-+-t-+-t-t---+-t---+.---1
CYCLE 4 I SPUTl
CYCLE SPUT 2
LENGTH !-"SP!:!L"IT,,3'--t-t--tI-+-+---+-t--I--t-t--I-+-t--+-t--t-+-+--+-t--tI-+-+---+-t--f-+-+---+-t--Jf-+----jIQla SPLIT 4
CYCLES I SPLllij rCYCLE SPUT 2
LENGTH r-eSP!:!L,,'T,,3'--t-t--If-+-t----t-t--f--t--t---t-+-t--+-t--I-+-t---+-t--If-+-t----t-t--f-+-t----t-t--f-+-ISPUT 4
CYCLE 6 SPUTl
SPUT 2
""UT 3
SPUT 4
CYCLE7<lsPUT 1
CYCLE SPUT 2
LENGTH !-"SP"L"IT,,3'--t-t--tf-+-+---+-t--f--t-t--I-+-t--+-t--t-+-+--+-t--tr-+-+--+-t--f-+-+---+-t--f-+----jSPUT 4
CYCLE 8 I SPlITl
CYCLE SPUT 2
LENGTH r-eSP!:!L,,'Teo3'--t-t--I:-+-t----t-t--f--t--t---t-+-t--+-t--I-+-t---+-t--I-+-t----t-t----Jf-+-t----t-t--If-+---1SPUT4
-J L-TratrlCCDntrol.....,TC,L Technologies
•••••••••••••••••••••
••••• • • • • • • • • • • • • • • • •
(0009:
((>009)
ON/OFF
N/A I N/A
N/A I N/A
NlA I N/A
8 I 9 I 10
(0-255 MINUTES)
7•543
DETECTOR FAIL MONITORING
2
DETECTOR FAIL SAMPLE PERIOD
MINIMUM
MINIMUM
MAXIMUM
FAIL RECALL
SYSTEM DEl
LOCALDETECTORI 1 I 2 I 3 I 4 I 5 I 6 I 7
1-8= MANUAL, 13 All OTHER MODES QR'Q
ON/OFF, 9=CLOCK, 1O",INTERCONNECT, 11 ""CQMM, 12=AUTO
COORDINATION SELECT MODES
ON/OFF, 9",CLOCK, 10=INTEACONNECT, 11 =COMM, 12=AUTO
1-8= MAN, 9=CLOCK, 10 = INTERCONNECT, 11 =COMM, 12=AUTO
1-9=MAN, 9=CLOCK, 10=INTERCONNECT, 11 =COMM, 12=AUTO
1-8=MAN, 9=CLOCK, 10=INTERCONNECT, 11 =COMM, 12=AUTO
MEMORY PROGRAMMING (PE's 6-10 are low priority)
, I 2 I 3 4 5 • 7 • 9 10
0-13 .3 2 2
0 0 0 I I 0 0 0O=INHIBlT, 1= MEMORY OFF, 2=MEMQRYON, 3= RECALL
DETECTOR DELAY
2 I 3 I 4 5 • 7 8 9 10
NlA NJA (0-255 sees
OFFSETS and MAX DWELL I SIGNAL PLAN TO SPUT UNKING *
CYCLE I OFFSET 1 OFFSET 2 OFFSET 3 OFFSET 4 OFFSET5-1MAXDWE~ SIGNAl PLAN l' 1 2 1 31 4151 .171 8
0 " 0 ;, 02 I'l n 0 0 0 0 O=NO UNKING, 1-4-LINKSPLIT 1-4 TO SIG PlAN
3 Il I"l I"l 0 0 0 I OffSET SEEKING MODe
4 1\ 0 0 0 0 0 I MODE I ~ I o = RESYNC 2 = SHORTWAY
5 /') Il n 0 0 ~ Immff1Mi@It }):'?IIIJiq£_ 1 = DWELL 3 .. INTERRUPTER
• 0 0 0 0 07 /') Il 0 0 08 0 0 0 0 - 0
FlASH I q
SPLIT I 9CYCLE I 9
OFFSET I 9
SYSTEM
SIG PlAN I /,3
•••••••
••
•
••
•
••
•••
••PRE-EMPTION SEQUENCE copes (Pre-empt sequence chart on back)
PE STEP II = Sequence S1ep"# 1-99
INTERVAL CODES
a = NOP (can be used with JUMP or VECTOR instructions)
101-832 = Display specified interval (1 st digit = signal plan)
841 = Clear Hi PE Call 1 851 = Clear La PE Call 1
842 = Clear Hi PE Call 2 852 = Clear La PE Call 2843 = Clear Hi PE Call 3 853 = Clear La PE Call 3844 = Clear Hi PE Can 4 854 = Clear La PE Call 4
845= Clear Hi PE Call 5 855 = Clear La PE CaliS
860 = Crear All Calls
900-999 = Pre-empt Exit Re-sync. Second 2 digits 0-99%. Used tosync Pre-empt to cycle timer. If cycle timer is less than specified percent,
hold in last displayed interval until cycle timer", % value, then
execute JUMP instruction. If the cycle timer is greater than % value,
immediately go to next step,
98 '" RETURN to normal operation at end of current interval, only clear
calls that initiated that PE transfer.
99 '" RETURN to normal unconditional at end of current interval (clear all
PE calls).
MIN"'" Minimum time of interval. If vector instructions are used with
higher priority PE, vector will wait for MIN lime.
Normal (MAX) time of interval if no higher priority vectors take
place,
HOLD ON INPUT, 0-10; 0= No hold, 1-5 = Hi priority pre-empts,
6-10 = Lo priority pre-empts, If 1-10, will hold until input goes
away, or vector override, or override/fail.
JMP '" Jump Instructions001-099 = Jump unconditionally to specified step
101·199 = Jump on Hi PE Call 1 to step #1-99
201-299 = Jump on Hi PE Call2to step #1-99
301-399 = Jump on Hi PE Call3to step #1-99
401-499 = Jump on Hi PE Call4to step #1-99
501-599 = Jump on Hi PE Call5to step #1-99
601-699 = Jump on lo PE Call 1 to step #1-99
701-799 = Jump on Lo PE Call2to step #1-99
801-899 = Jump on Lo PE Call3to step #1-99
901-999 = Jump on Lo PE Call 4to step #1-99
,01-,99 = Jump on Lo PE CaliSto step #1-99
Vl-5 = Priority vectors 0-99. Jump to indicated step if higher priority PE
becomes active (after MIN time). Only jump if PE is higher priority
than active PE and there is a valid vector step. If more than 1
active, highest priority PE takes precedence.
Intersection Name'-
PAE·EMPTION SET-UP PARAMETERS
PRE-EMPT IN H1 H2 H3 H' H' L1 L2 L3 L' L5
DELAY BEFORE PRE-EMPT
"LAST X" SECONDS (HOLD)
MINIMUM RE·$ERVlCE
OVERRIDE TIME
FAIL TIME
PRIORITY I d .3 4 5 6 6 6 6 6
EXIT FLASH 0 0 0 0
~HIGH PRIORITY PRE-EMPTS DURING MINIMUM RE-SERVICE
LOW PRIORITY PRE-EMPTS DURING MINIMUM RE-SERVICE
LMD 40 Pre emptIon Data Chart
DELAY BEFORE PE = 0-255 Seconds
LAST X SECONDS =0-255 Seconds; Specifies the "last X" seconds of the
delay before pre-empt, during which the LMD40 will not terminate intervals
designated as "PE DELAY HOLD" intervals (related to that PEl. Prevents
starting a new interval just before pre-empt actually occurs.
PRE-EMPTION SET-UP COPES
MINIMUM RE-SERVICE = 0-99 Minutes; Specifies the number of
minutes, after a pre-empt, before a new pre-empt is aliowed (see PE's AL
LOWED below)
HOI =FAIL TIME = 0-255 Minutes; SpeciJies a fail time beginning with activation
of the input. If the input remains active and the timer times out, the pre·
empt input wJII be canceled and pre-emption will be overridden, The unit
wilt return to normal, then cycle to remote flash, De-activation of input
resets timer.
EXIT FLASH = 0 or 1; 0 = PE sequence does not override remote flash,
= unit will exit remote flash into signal plan flash exit interval, then pre
empt from there. Low priority PE's cannot override flash.
PRIORITY = 1·5; Sets priority of pre-empts, where 1 is the highest, 5 is
the lowest. Equal priority; First come, first serve. Note: low priority PE's are
all priority 6 (lower than any high priority PEl and are not programmable.
PE'. DURING MIN RE-SERVICE = 0-255 Pre-empts; Specifies the num
ber of pre-empts allowed within re-service period before MINIMUM RE-SER
VICE restrictions applied, (e,g. 2 = 2 pre-empts oould occur within the
re-service period, after some initial pre-empt. Thus, use "2' if you wish to
allow 3 pre-empts in a row, "3' for 4 in a row, etc..
timer.
OVERRIDE TIME = 0·255 Seconds; Specifies an override time beginning
with activation of the input. If the input remains active and the timer times
out, the pre-empt input will be canceled and pre-emption will be overrid-
den. The unit wJII return to normal or other PE. De-activation of input resets MAX =
rcr-TrafflC Control..., ~Technologies •
PRE-EMPTION SEOUENCE STEPS
STEP # INT MIN MAX HOI JMP V1 V2 V3 V4 V5 COMMENTS
I 103 7 131 FDW
.;I 108 JPI - 08
.3 .:131 JP.;I-.31
4 .,ob JPLI-Oh
S "131 JPL.:I-.3f., 1.31 10 #/0 0 8 .3f LP€ *1 HOLD ¢.:2.
1 04/ JNlP T.o 41
8 13/ 10 Ao I 04/ HP€ *I,JNJP TO 41
9 NOP
10 NOP
1/ 105 A .£ILL R€D KED REv
1.:1 105 .;I 101$ ALL R€D, JPI-8
13 ,;i.;i,8 JP.;I- .:28
14 {,Ob JPLI- 06
/5 7.;1&, JPL:J ,- dl/o
I&. 1/1 JPI- If (ReD ReV)
11 ':<1:>' JP.;< - I~ (11/.0 RED REV)
18 bl I JP{/- If (RED REV)
19 (J/~ JJVlP 7.0 I~
.:?O Ifd? 4 (JI;J ($3 fE'L, JrvlP- I~
AI 1~5 JPf-A5
,;i.:l I- .;/.;1,8 JP,;}- .:18
.:l3 1..;1,5 .jPL/ -.;16
.:14 7':<& .jPL;I - CltD
.AS 1,.;(0 4 (J 1,.;( {64 y",,- I JNlP To 1.:2
PI'" 13;1 10 .:10 7 .;15 .:18 LP€ iFf HOLD (44
,;i1 054 JNlP T.o 54
,.;(8 13.;J. 10 .;/0 .:I 054 A5 I-/PE #.:1 JH1P To 54
.>19 NoP
30 NOP
.31 104- 4 01.:1 ¢I YEL) JMP To Id
~ If,;!, JPI- I.;J. (No RED REV)
33 .;ll f JPI- If (RED REV)
• 1-¢
••••••••••••••••••••
PRE-EMPTION SEQUENCE STEPS
STEP # INT MIN MAX HOI JMP V, V2 '" V4 VS COMMENTS
.34 IM~ Jpt../- 1;/ (No ReD ReV)
35 111 JPL.:1- If (RICD ReV)
3"- l;lfI 4 O/~ 1711 YeL JMP To I;;
31 .;119 '1 1.:15 ¢ 1- F1>k/ JPI-;;.s
38 ~8 JP,;I- ':;8
.39 ~5 JPLI- ~5
40 7:18 ..}PL,:)-,.j8
41 91fp Mt. W"'T 'TIC 1"- 'l. JHlP 70 4(.
4;;( 93A 048 WI'/" 'TIC -38'2 JJvJp To 1-/343 91.'1 051 W"'T '71<_ 671£ JJvJp To SI
44 999 045 WAIT'TtL 99'2,JNJP To 45
45 O? 041 Loop 51'/Ck; 71J 4141. 104 4 ¢.:I YeL
41 99 RET To NoRNI
48 104 1- ¢.;I )leG.
4') 11.3 1 RE'D 8EFo"'le 1714-
So 99 RET To NOR""
51 104 4 ¢.;l Y€<
5:l 1,;1 I I Rt!D 8eFoRE (41
53 99 RE'r 70 NoRIVI
54 9a5 010 W4r,. 'ne.. 5'll , JuMP 70 7055 910 010 W~ur 'TIt- IO~J ..Jump To 10
5{, 915 070 AJttJI T 'Til.. IS'll JumPTD ,()
51 9;10 010 A/j:llr ITJ(.. .,.a,~, JUfY?P To 10
58 9.;>.5 010 W~/r JTJl.. ..2..<)<2, ..JUNlP To 7'0
59 930 070 WAIT 'TIL ..30"&, Jump To 10
(.0 935 010 WttJrr 71t... ..35~, Jump TO 1lJ
{,I 940 010 A;~/T 'TIL 4ottz" ..Jump 7'0 70
t,..:l 945 010 W,qtT 'TIt.. 45'll, Jump To 70
0,3 950 070 W41T 'TIL 60~. Jump 7'0 70
M 955 070 W41r 'Til. 55~ Jump To 70{,5 9M 070 Mrr 'TIL {,O 'Z Jump T. 70
(." 9{,5 010 W,qIT 'TIL {,S't, Jump 70 1"
•••••••••••••••••••••
PRE-EMPTION SEQUENCE STEPS
STEP # INT MIN MAX HOI JMP Vl V2 V3 V4 V5 COMMENTS
67 %1 077 WRIT 'TIL &'1~, Jmp To 77~8 07/P IF" >~7~ Jmp To 7~
to9 NOP70 I~o 4 d4 Yel...71 l/ll 1 ALL ReD7.;1, I';;:l 15 ¢I GRN
7.3 IoRB 4- ~I Ye'L
74 1.:l9 I ,t:J(,.L ReD75 13f 1 04( ¢:;J YE'L, JmP "-041
7~ 1.;/0 4 074- ¢4 VeL, Jmp To 74-
77 I~O 4- ('!4 Y€"<...
78 99 ReT To NoR"'!
NOTES:
LMD40 Signal Plan Chart Intersection Name:._----'-8"''¢_-------------Signal Plan Number :_L..I__
. """'" • , 2 , , , • 7 • • ,. " " " .. " " " " " 20 I" 22 I~ " ~ " Z7 2' ",. , ,. 100M
/ R 1 X ~ XI • IXI 3, X X IXIx r'><'" X X X ><, IX
• X7 : IXIX x 'X
.3 • X• X D<,." X
"" X X 'x 'XI'>< X- X
1.5 .. IXI~ " X.:> b J ,. t=" Ix X IX X- X
".:l '" 16It; /< " ~ '>'!./- ~ X
I"" ~ ., X14 .D;J '" X X X IX
~
14 J<J ..IR Ii' " IX X. X X )('
IR Y "r- Z7
Ii' " X IX X X ~ x X X IXIYI'>< X. XY ~
M
.- X I'><' '>< D< X X-IX
33 X X
'" X I'><'IXIX 'X 'X X IX X X X IXX X IX X X IX IX" X30 X¥
:I>J .. F x X '>< I'><' X X X IXIXXW '" X XbW " X X XW .. :....
ptf/ '2Pt::z <3
pE.~ "PE4 .,..47....
Add Time To I I / I / I I I I / I I / I / I / I I I I / I I I I IN::tUlllions II? n IR IR "il 8311M 183 '-3 M M 184 1114 184 '114 4M 61 IHI 18/ 81 II/ 81 ,,/ "~ q;; ~ 1'15 ll3 .~~ q~ 44 94 1'14- 94- 1'14- ,qq 4- ql 91 I'll I'll 'II 91 19/
~vlnhlbit I.XIX I'><' X 'X f'>.< IXAI a Timl IX X
~- ~ .:l .:lHI prioritv PF Xl, r I I .:I ,,2 .:1 'lil 33 .33 133 5 5.3 "" 5' 5' 5' 51 615 9 (,9 ''I .91-"" 12'1
Low ~ ""*' Pt:)(fer I I ,,2 2' 33 33 33 !l!l 1.3'1 33 5i .5!l .5 57 51 51 '2 !a "9 '9 (,,9 f.9 ,,9 (,' 127 .;nPE~--
Hold
"'00«
'"'" <" XClIck! Xfer XS<>lilXf"r X
~ l'Iai PI n Vier 19t> I'll 1M 0 194 'I'Minimum TIm;na '1 " 1"1" .'1 1"1" .'3 5 .3
nCT 1-(1 • ¢1-8
nCr 10 = 4 f (I 1'£1>
JIlL Ptf 1 = 1+'"
fljL P€;; = .;/ +5
111< Pe.3 = .3.8
JIlL Ptf4: 4.7
---J '-TraffIC Control....{C,L Technologies
LMD40 Signal Plan Chart Intersection Name:_-<-8.lj¢I£L-_---'-(.,,3!1f""'B;.u) Signal Plan Number: ~
--=- --=:"" # 1 2 ~ , ~ • ,--;- ." 11 I' " " " " 17 ,.
" 20 I" I .. i .. " - 26 i " 26 " 32 I~M
I R , X- iX' IV V '" rx V I'><' '" v 'X X'--, " 2 'X'3 r:.c V IV'>i, V '><' I'i7N X5 rx•, r'V V 'VV V I">< IV
.3 ~ 'X', '><' V,. R7"'i7 ';; V "" '><' .f( 11 'X'
12 i X' I'><'~ V K.> !'.?~ "" ">Z i'>? N rv !'V v 19rv I'><'
" 'X'," ':X '><
1:> ~ I ,- ~ ':X 'XI">< '>< I">< V V I'><'17
"" L "/: '" "...... rxIVI'><' I'><' r'><' "'" X' '><' V Y X- X' I'><'IV f'...I
-;20 """--z " "IA b~1 22 V "" .", '><'IY '><' X' I">< rxIVIV'-
4 w '-;U 25
'y V 'X~ I'><' I'><' I'><
" 26--r- 2'b
" 'X X- I'><' rv -X I'X IY
" '--:< '-
I,. x: rx X IX IX x:,,,"R "<'3 -1/35 ~
r.o 7.: r;;: rv rv I">i1"- 7>J.I I .. ~ ~ IX Do1/, .1 I •• I'><' "'"rD bW = y I'V'rv ">Zrv IV V Y '" V V IY IV I'><' i'><'""rD --.:J ....
lUI #2P.<'.:> #3
PC:'" ..fiFX -;;-
#6
"#6..
Add Time To / / / I / / / I / / / / / I / / I I I I / IAc1uations '" a ""ILl E re: l? '''3 F- '''A IDA IR< 1"- 71 I ~I hi I ~I 71 IL
Resets ''''' II?> 113 113 IR<I!t3 o?< Iqd 14 104 194 1094 I... 101 191 19/ 191 191 I'll I-;.
Inhibit '" I'V "><' 'X' -XAuto Timin " rv ""TV I'><' ...... TV-".. O~
::J .:>H~· ·~Xfr I -, ~ l' I",. I.". 74 "4 I~. 14' I'" .5 57 I... · L4 I::J?
Low .......... · PE Xler I I Ol ;1] ;>J179 79 79G<i 70 7a 9Z 9~ 57 57 5J 57 571'<, I..., 5- IL" LQ :l1 ,.2
PE 0.1&" Hold
HoOd
Force 0I'fFIa$h Ent-· 1'><
--:::: XIMI'>;'
---;:;-01. Xferr<;;
N n.al Plan)(fer I 0 1..~la'
t,Alnlmumnm" 7 .3 5 I~ I~ ,~ 5 .'!
/leT 1-8 • ¢1-8
/leT 10 : 4 ¢ tJ t=Eb
II/L Pc I : 1>/0
1-1/< PE';; : ';;>5
1-1/< PE.3 = .3 >8
II/l P€4 = 4> 7
-J L-TratrlC Control-fC,L Technologies
LMD40 Signal Plan Chart Intersection Name:_....J-84¢"'------'(L4L.!-+--'.1-'-)'---- Signal Plan Number :--'3=--_
• """,oJ .. I , , • , • , . " 10 11 ,. 13 " " I' ",. " ~ 20 '" 23 2#
,~ 26 , 126 I,. 30 " 32 I","I R I IX X '><: X Y X- X IX IXIX X X X .:>< XI 2 XI 3 ,: .....
• .. IX X, ~
• 'X .x X .'.
, X- X X X X 'X X X X X I"><•
.3 •4 10
11 X',. X.IXIX ::x i"><" V
'" X X LX X IX
" IX
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b •1 .. t=" '>< l.><- X X
"" X- YI. '>< IX
/.. 20 X
'" '" X X X-d 1>, .1 ,= 'X IX X X- iX X IX 'X X X X X- X IX
'23
4 W .. ..:.26 X X ><: IX:"x X- X X X IXIx 'xX ><2627
I~ '>< X-IX:X X X X 'x X IXI~
'30
I" X X .XIX X X IXI~ X
33 'XIXIX X3#
" IXt= I .. :><
c. ZHI I" F X X X-i. W I~ ,x:X- ..
X- X rx X IVI"'>< 'XIXIX' X- X8 W #()..
PEl #2PE #3
PE ..p,:. .'..
"..Add ilme To I I I 1 / 1 I / 1 / / / I / / I / I / /Aclue.lions R II A II C7 E7 E7 £ £7 1...4 I..... Rd " 7/ 7/ 71 7,
~ " IV R7 117 R7 R7 R7 R7 "'I- 1'14 1'14 '1'1- 194 'N 4- 1'7. 9/ 1'1/ 9/ 9/ 191.. Inh·"" IX' IXIX X X- . ><: XAu(oTomlno IX X 'X X- X X~~ ;l ..< 71
HI PriorItv PE )(fer / / .71 .;I .;I ~3 33 133 I•• ,,~
~5" 53 "" 5~ 51 51 !S1 .5 5. ~ (,9 "'I 69 71 :11
LOW' p""""" PE )(fer / / .71 .;I ;I.~ 33 .3.3 33 .3.3 31 53 5.3 5~~7 57 51 5.1 51 5:'l 5:'l 69 6' VI (,'1 (,9 1"9 ;11 .;nPE Dela Hold
""'"F""'" otl
...... e.. .'X~ .~~ XSol~ Xler X
<::1t1 n Plan Xfer IhO Iq.t Iq~
Minimum 11mi 7 " 5 .-'l I"; .~ 15 .3
ACT 1-8 • (41-8
fie" 10 • 4 f 8 Rob
1I/L PE 1 • /flo
JI/L PE;J ~ .;; +5
H/L PE.3· .3,8
1I/L P€4 = 4 + 1
-J ~TrafflCControl--fC,L Technologies
LMD40 Signal Plan Chart Intersection Name:_---'-8'-J'0""'--_>-(.!.I.!.T--'6!<.L) Signal Plan Number: 4
. ""'''''' # , 2 3 • , • 7 • 0 ,." " " .. " ,. " ,0 " 20 " ~ ~ 2'
,. 26 '7 129 ' 30 " 32 noMI R , ~ X- X 'X- X' X IX'X' X 1:>< X X X IX,X X
2 IX3 :x- X X IX X X X• X X X '><' I'>< X X IX, X
.:; • x" 7 X IY X X X IX X IX..3 • IX, 1"><- X X X rxIX',. X X X- iXIX
Y " X
"'.
'" " X IXIX X X Ix.. x IX IX15 ....<;
" IX .~.:; b .J ,- F" >< X- X LX
".:2 " IXI"X'It.:. " IX IX. X X X IX X X X X X .>< IXI .<. 20 X
h .. X X IX D<1<1 1:> .1 22 X IXIXIX X X X X X X ex LX
I"4 '" I,.,. I'x' I"X'IXIXIXIYX X X IX 1:>< X I"" IXIXIX>< X IXIXX X X IX IX IX
26
27
" IX' X 1'><'IYIXIX X I"" X IXI'x'IX X X "X' '><'IX1'><I'x'X' X IXIX IXI?OI~
Q I" IYIYIXIX rx IYI'x' X X IX X X132 X.
33,. IX rxrxrxex X '><' IX X '>< X X IX X X "X'rxrx X'35 X36 ,,><: x X
Z>IJ I .. F" IYIX,'>< IXIX '>< '>< X ')( I'"IV 138 IX. X X- X X
7>W 39 >< IX :>< X X ex X LXW ..
"PEt '2PE.2 .,PE3 "PE4 "
""""Add Tlme To ..•. J J I 1 I 1 I / 1 I 1 1 I 1 / / I I / / J / / 1 I I I
Actuations IR Il R R ,~ 8.3 R~ Ill.. 111. 6.3 64 1/4. IR4 1114 111.4 111.4 t'A t.4 M li'l 18/ II?I I?J 8/ " "-." ..... 9..3 93 99 ~ 193 93 93 I.... 04 104 94 104- 144 q4 ql 9/ 101 Iql 91 91 Iql
"""" Inhibit >< X X X X Ix..A Tim"n X "X ><IX X X X XPE ReSDOI'l$e .;< .;< .:l .:2
HI Pri . F'€Xler / I ,;I ,2 .. : .~ ~.3IB I~~ I~: 5." 5315'1 51 57 51 !!1 .5 5 19l. 19,<, 9,<,lowp,.- . PE Xfer I I .;; ~. ;1.'1 .3!J 33 .3!J .3!J r.. I.. 53 53 5' .-';'1 5'1 5'1 51 57 !iO !iO 9<!. 96 910 910 19~ 9
PE Delav Hold
Hold
F .~
F\a$hEnltv X
"" XI~ X<:... itXfef X
SItI".r PLan)(fer
M.nimum Tim; 1'1 " 5 ..3 I." .3 .~
/leT 1-8 = ¢1-8
/leT 10 0 418 Pcb
JI/LPE/~ Ith
I-I/L PE;; 0 dI +5
H/L PES = .3#8
JI/L PE4 = 4 # 7
---J '-TraffIC Control-fC,L Technologies
LMD40 Signal Plan Chart Intersection Name:__-'8..yo¢-'-----'-(-"O?o...LT~5"_")'____ Signal Plan Number: S
. "" # 1 , 3 • 3 • 7 • , I • " " " " " 18 17 ,." ~ '1 22 23 I " I~ .~ '7 ,.
" 130 131 32 DO", X X IX ~ '><" X IX X X X IX IXC>< X,3, 'XIY "" X- X, IX• X X
R 7 X- X 'IX .....•... X• X
-3 " 0 x4 " 10 ~ X X IX X X X X X4 )I " X4 r-;
" IXI~ X XR .. IXIXD< X
" IX~ 13 .. X X X
DW ,. F X IX IX X X X 'X F17
.;/ W 18
I.e; ,<, " X .>< X Do: 'XIXDo: X IX1.<. ~ IXIt. IE " IXIX X14 1> '" " X X IX" X X ~ X-Ix '><" X X-
=14 J.I ,1.<1 R 23 X IX X X XI .. Y 23.. '" 27
Zl R ,. IXIXIX IX X X X ;x. X X !/< LX X X1.11 Y "B ~
7 IXD< X X X- .",. X X D< X ">< X7 132 ..:x7 33
I ... I? .. IXIX X X IXiX X"IX.'X" X X X IX X,1/ y 33 X... ,; I- X
7>LJ .. F X X X X Y IV X Y IV X X X X-IXIX IXiX XW I" X IX
DW 130 IXIX X X IX X. IXW #0.,
P(;f ""P/£:> "P€3 ..P€~ ..,.
.,....AddTIIMTo J J J J J J J J J J I I I I I I J I I I I IActuations IR 11 .. /I &'i I.. 1.1.4 84 R4- 1/4 11/4 8~ £5 a .5 £5 £5-,. q. q~ q, Iq~ Iq~ 9.'1 q" 1"4- 194 "" <>4 I.... 1# R5 1/5 R5 1/5 M R5 1M....... Inhibit X X ,;> IX X X
Auto TImi IX X ,;> X X X IX XPI" Re..oon....
H" , I / I'" ~7 ;'7 3~ 33 33 3'l I!B 133 53 53 57 57 ,. 57 5 '7 5. 9' 197 197 97looP' PE X'er J / .:> ~ :17 ~~ ~, 3~ ~3 33 3~ 5 IS ~ 5 5 57 53 53 97 9' 97 197 97 ,97
PE Delay Hold
Hold
'" .~"""'E XCvc'- Xfer IX<::, ~ Xfer X
SI naJ Plan Villi I
Minimum T1mlna 1 .3 15 -3 5 .~ .'l
--J I.-.TrafflC Control--{C,L Technologies
LMD40 Signal Plan Chart Intersection Name:._----<.8..,YlI'L-_>-(4"'--'+'-'-8'-'P'--"e"'D<.)L.- Signal Plan Number: 0
I
I
xX
x
IXIX
XXIXX
IX X XIX XIXX X XIX 'X'
XXXIX
IXXX
VIXIXXX
XIX.
I ........ ............. . .
XIX X ""IX X X XIX'X
I
,.. ,
........... IX
IXX"'X'XXIX"l><
:; 6 1 a 9 10 11 12 13 14 15 16 17 18 19 20 21 22
XXXX~ XX·2·3' ., " ., X
",'?----
13 ""><::' 'X"'}<14 :'':.:.'.:-:::.::
• XXX.
•,r;> '0 XXx.x
R ".,.Si081"I-1234
1!'\':::':': I ",:1> J,...... .c-IXIXXIXX"l><
17 1:·::-:: 1---:
5
•I
".3
5
II-'l.:I
18 XIX·" ·······I><IXX X20 :><.
" X
XXXIV
x
1&
4
~,/~XIXIX XXXIXIXXX FFFFIFIXzi...... I·· ..
IV I" I·.·.·.·... I·.·· IX26IXXI'><'IXX~XXIXIXIXXIXIXXX
XIXIX
26 I
18113
2' ......
I '. IX X I,><,IXCX X X129 . ..I~ I .. ·.. ..... .
XIX X Do< xxx XIX
XXXXIXiX
XiX
IXIXXXX. ..
........ i
IXIXIXCX",IX
r IF FIF F XIX"
xx
X
...... IXIX
XXXXX 'X'IX XXIX
......
.
FXX..
l:llIXI"X32 '.
33
]) iJ '" .......W 3!l CX"""
:DW 39 IX
1'1'
Pcl 42
PC-::Z 43
PE3 «Pc4 45
Add Time To
Actuations
Resets
Shoffwav Inhjb~
Aulo Timl
P£ ReSDOnse
Hi Pri . PE Xfer
low Prior" PE Xler
PE Delav Hold
11111111111R 11 R R ;;.~ 83 8.3I/H '3
,;t 93'''39.31'' 9" 90, ROXX
.;< :1
/ / -:2 .:I .2 13.3133 58 63 3:
111111116/1""1111 /<1/1/1,1/1 Iiol "
Iql 91 "I 91 91 91 IXX XXX X.'l
51 .51 53 ~1""9 '-9 9.,9 9 69 ",1
Force Off
FlashEnl XCvde Xfer LX.S litXfer X
Siona! Plan Xfer IMinimum Timin 7 ~
IIcr 1-8' ¢1-8
lIeT 10 • 4 ¢ 8 A!/)
illL Pc I • '+10
JIlL Pc;) ~ ';;+5
!-IlL PE.3 • .3,8
ill~ Pt:4 = 4, 7
-J '-TraffIC Control--fC,L Technologies
LMD40 Signal Plan Chart Intersection Name: 8¢ P€ INT€RvALS Signal Plan Number :--<.8""---_
. ". "" • , ,3 , , • 7 . • I. 11 I' I- " " I' 17 I' I" I- I 'I 22 23 " I- I- 1'7 , ,.
29 30 " 32 D4MI 1 '5<' rv """IV Y V 'i!'""" I'i7 ""ii' rvI'i7 X rv 'V'IX IX"""7" --=- 'X,
3 C'>C """ -X
'" , y 'X V I'><' I'v Y '5<' '" "" ":>< 'X-;- "" I'i7 "X 'X
'><
· 'X 1'>< X
· I'><'St I'><'2 '" --=- '5< 'ii' "iii:14 &> ,. X -X "X 'XIY Y4 11 r><' 'X ~ V
-;:- vI" I'>C '>< "X D< C'>C -X '><I •• N "X "X
-=- 'X-:;;- :J) " :::- I'i< "V v I'i< '" X X F I'><'
17
""
r<;; v "5<' I'i7rv S7 y I'i7 r'W' 'VI'V'IVI'><" r><y ~ IX X
/. I",
" Ci "-rv v IVrv V I'>C V I'w ....... """ V IV IXI,.
1./ I ..
'"r-;;; v 'V "5<'""" I'><' '>< 'XIV'
28
27'0 I" '"Y 0-r-. 1---z> I:; I"X
" "- I'>C I'><' IX--;:::
331> " IV rx '>< 1'>< "X I'><' IX IX IXIX I"X "XY 30 I'><' I"X ""X rx
-;;: "5<'7>l.J I .. "" "X rx FW =
DU = 'V1'5< rv '><' I'><'LJ '""
"IV
PGP #3 YPE3 "
'XP€A -=- I'><'
, .."~..
Add Tlme To
Actuations.......--= Inhibit
Auto Timl----;::-Ro 0
H~· . --=-Xfer
Low~· PE XI.r
PED; Hold
Hold
F--~
Flash Em
--;:: "Xl"~'i1Xfer
"',. nal Plan "f·r
MinimumTiml
-J L-Tratrlt: Control-fC,L Technologies
LMD40 Per Unit Programming Data Chart
Intersection Name:__"'8'-J0"'--- _
PER UNIT DATA
ADVANCED FLASH RATE 0 0-60,1-120,2-150,3-180
NUMBER OF INTERVALS ~9 ()-32 INTERVALS
50 or 60 HERTZ 6 6~60,5-50
MINIMUM FLASH 4 a-255 SECONDS
PER SIGNAL PLAN DATA (specify designated interval 1-32)
[jSIGNAL PLAN 1 2 3 4 5 6 7 8
FLASH EXIT I I I I I I I IDWELL 01 <R .R ~ ~ <R A .R
INITIALIZE f f I I I f I fSPECIAL SIGNAL PLAN TRANSFER CODES (0 ~ DON'T CARE, 1~ SELECTIVE ACTUATIONS)
Sig. ON ACTUATIONS AND NOT ON ACTUATIONSCode Plan
1 2 3 4 6 8 9 10 1 25 7 3 4 5 6 7 8 9 10
90 dI X X91 .3 X "'><92 4 'X. X93 6' X X94
95
96
97
98
99
SPECIAL SIGNAL PLAN XFER ACTUATION CODE
These special codes can be assigned in the signal plan transfer blocks to allow transfer based on user defined data. Foreach code to be used (90-99), specify the signal plan as well as the "on" and "not on" actuations by placing a "1" under thedesired actuations. Place D's if it doesn't maner what the actuation is for the indicated logic.
fer-Traffic Control..., ~ Technologies
•
LMD40 Timing Plan Chart
Intersection Name:_.L8.;~q5I.- _
(continued on back)
~ INTERVAL 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
CYCLE 1 SPLIT' to J 113 4 1 $. .,;} .:1 ,£J .tl i:< 4 I ,J) A ;.3 .3 -3 ;.3 4. I ,5 ··tfl .;l .;1 .5? Po·· 14 f .....
CYCLE SPLIT 2LENGTH SPLIT 3.!&.
SPLIT 4
CYCLE 2 SPLIT 1 N" I IJ~ 4- I .5 ..:l .;? ~. <R ,.:; 4 I .5 c"3· ;.3 .3 :5 :a 4 I .5 ·IR· 61 ~ oR· 1b.1 <I ( .,. ....... ';
CYCLE SPLIT 2LENGTH SPLIT 3Laa
SPLIT 4
CYCLE 3 SPLIT 1 ~n I /dJ 4 / .7) .q .q 3 dI .;1 4 I .')' )'1 i-'? ..3 tA I.;;> 4 I 5 ..3 ..3 .<3 ,.:; ..:;. 4 'I , ,.CYCLE SPLIT 2
LENGTH SPLIT 3I/O
SPLIT 4 ICYCLE 4 SPLIT 1 M I 1.3 4 1 .5 ..3 -3 ..3 .:l ~ 4. f /Dl d -3 .~ ~ .:J 4. f 5 -3 ..3 3 .;z ~ 4 fCYCLE SPLIT 2
LENGTH SPLIT 3fril1)
SPLIT 4
CYCLE 5 SPLIT 1,.. I·' .•. I·'" i> .,." >
,. .. > .} ." .. I} I·'··· }' ;::: 'nI' ,:,::., ,,}CYCLE SPLIT 2
LENGTH SPLIT 3-- SPLIT 4
CYCLE 6 SPLIT 1,. ..
" •••• 1/CYCLE SPLIT 2
LENGTH SPLIT 3-- SPLIT 4
CYCLE 7 SPLIT 1.. ,. , I. . ' . ..., ,... ..
CYCLE SPLIT 2LENGTH SPLIT 3- SPLIT 4
CYCLE 8 SPLIT 1 .. , I •• .. ' . ••
CYCLE SPLIT 2LENGTH SPLIT 3- SPLIT 4
fCr-Tramc Control-, r- Technologies
NlA IN/A
N/A 1 N/A
N/A 1 N/A
8
8 I 9 1 10
(0-255 MINUTES
76
o ~ RESYNC 2 - SHORTWAY1 = DWELL 3 - INTERRUPTER
543
DETECTOR FAIL MONITORING
SIGNAL PLAN TO SPLIT LINKING *
2
2131415161718
{) 00= NO LINKING, 1-4- LINK SPLIT 1-4 TO SIG PLAN
OFFSET SEEKING MODE
DETECTOR FAIL SAMPLE PERIOD
MINIMUM
MINIMUM
MAXIMUM
FAIL RECALL
SYSTEM DET
LOCAL DETECTORI 1 1 2 1 3 1 4 I 5 1 6 I 7
9 I 10
N/A 1 N/A
874 1 5 1 6
DETECTOR DELAY
OFFSETS and MAX DWELL
3
OFFSET 2 I OFFSET 3 I OFFSET 4 I OFFSET 5 IMAX DWELL
COORDINATION SELECT MODES
2
2 I 3 I 4 I 5 1 6 I 7 I 8
o
oo
ON/OFF, 9-CLOCK, 10= INTERCONNECT, 11 =COMM, 12-AUTO
ON/OFF, 9= CLOCK, 10=INTERCONNECT, 11 =COMM, 12=AUTO
1-8= MANUAL, 13 ALL OTHER MODES OR'D
o
o
ooo
1-8-MAN, 9= CLOCK, 10= INTERCONNECT, 11 =COMM, 12-AUTO
1-9=MAN, 9=CLOCK, 10~INTERCONNECT,11 =COMM, 12=AUTO
1-8= MAN, 9-CLOCK, 10= INTERCONNECT, 11 -COMM, 12=AUTO
MEMORY PROGRAMMING (PE's 6-10 ar.low priori
11/1/1/101/1/11
OFFSET 1
.3 1013131310 1-8 1..3
0= INHIBIT, 1-MEMORY OFF, 2= MEMORY ON, 3-RECALL
6
8
4
7
3
5
2
8¢
CYCLE
SPLIT
PRE-EMPTS
DETECTORS
FLASH
CYCLE
OFFSET
SYSTEM
SIG PLAN
LMD 40 Pre-emption Data Chart Intersection Name: 8¢
PRE-EMPTION SET-UP PARAMETERS
PRE-EMPT IN Hl H2 H3 H4 H5 L1 l2 L.3 L4 L5
DELAY BEFORE PRE-EMPT
'LAST X" SECONDS HOLD)
MINIMUM RE-SERV1CE
OVERRIDE TIME
FAIL TIME
PRIORITY / c:< .3 4 s 6 6 6 6 6
EXIT FLASH 0 0 0 0 6 0 0 0 0 0
HIGH PRIORITY PRE-EMPTS DURING MINIMUM RE-SERV1CE
LOW PRIORITY PRE-EMPTS DURING MINIMUM RE-SERV1CE
PE'. DURING MIN RE-SERVICE = 0-255 Pre-empts; Specifies the num
ber of pre-empts allowed within re-service period before MINIMUM RE-SER
VICE restrictions applied. (e.g. 2 = 2 pre-empts could occur within the
re-service period, after some initial pre-empt. Thus, use "2" if you wish to
allow 3 pre-empts in a row, "3" for 4 in a row, etc..
pRE-EMpTION SEQUENCE COpES (Pre-empt sequence chart on back)
PE STEP tI = Sequence Step tI 1-99
INTERVAL CODES
o = NOP (can be used with JUMP or VECTOR instructions)
101-832 = Display specified interval (1st digit = signal plan)
841 ~ Clear Hi PE Call 1 851 = Clear Lo PE Call 1
842~ Clear Hi PE Call 2 852 ~ Clear Lo PE Call 2
843~ Clear Hi PE Call 3 853 = Clear Lo PE Call 3
844 ~ Clear Hi PE Call 4 B54 = Clear Lo PE Call 4
845~ Clear Hi PE Call 5 855 ~ Clear La PE Call 5
860 ~ Clear All Calls
900-999 ~ Pre-empt Exit Re-sync. Second 2 digits 0-99%. Used to
sync Pre-empt to cycle timer. If cycle timer is less than specified percent,
hold in last displayed interval until cycle timer = % value, then
execute JUMP instruction. If the cycle timer is greater than % value,
immediately go to next step.
98 = RETURN to normal operation at end of current interval, only clear
calls that initiated that PE transfer.
99 = RETURN to normal unconditional at end of current interval (clear all
PE calls).
MIN = Minimum time of interval. If vector instructions are used with
higher priority PE, vector will wait for MIN time.
Normal (MAX) time of interval if no higher priority vectors take
place.
HOLD ON INPUT, 0-10; 0= No hold, 1-5 ~ Hi priority pre-empts,
6-10 = Lo priority pre-empts.1f 1-10, will hold until input goes
away, or vector override, or override/fai1.
JMP = Jump Instructions
001-099 = Jump unconditionally to specified step
101-199 ~ Jump on Hi PE Call 1 to step #1-99
201-299 = Jump on Hi PE Call 2 to step #1-99
301-399 - Jump on Hi PE Call 3 to step #1-99
401-499 = Jump on Hi PE Call 4 to step #1-99
501-599 ~ Jump on Hi PE Call 5 to step #1-99
601-699 ~ Jump on Lo PE CallI to step #1-99
701-799 ~ Jump on Lo PE Call 2 to step #1-99
801-699 = Jump on La PE Call 3 to step #1-99
901-999 = Jump on Lo PE Call 4 to step #1-99
.01-.99 - Jump on La PE Call 5 to step #1-99
V1·5 = Priority vectors Q.99. Jump to indicated step if higher priority PE
becomes active (after MIN time). Only jump if PE is higher priority
than active PE and there is a valid vector step. If more than 1
active, highest priority PE takes precedence.
EXIT FLASH = 0 or 1; 0 = PE sequence does not override remote flash. 1
= unit will exit remote flash into signal plan flash exit interval, then pre
empt from there. Low priority PE's cannot override flash.
PRIORITY = 1-5; Sets priority of pre-empts, where 1 is the highest, 5is
the lowest. Equal priority; First come, first serve. Note: low priority PE's are
all priority 6 Oower than any high priority PE) and are not programmable.
HOIFAIL TIME = ~255 Minutes; Specifies a fail time beginning with activation
of the input. tf the input remains active and the timer times out, the pre-
empt input will be canceled and pre-emption will be overridden. The unit
will return to normal, then cycle to remote flash. De-activation of input
resets timer.
OVERRIDE TIME = ~255 Seconds; Specifies an override time beginning
with activation of the input. If the input remains active and the timer times
out, the pre-empt input will be canceled and pre-emption will be overrid·
den. The unit will return to normal or other PE. De-activation of input resets MAX =
timer.
DELAY BEFORE PE = 0-255 Seconds
LAST X SECONDS = 0-255 Seconds; Specifies the "Last X· seconds of the
delay before pre-empt, during which the LMD40 will not terminate intervals
designated as "PE DELAY HOLO" intervals (related to that PE). Prevents
starting a new interval just before pre-empt actually occurs.
MINIMUM RE-SERVICE = 0-99 Minutes; Specifies the number of
minutes, after a pre-empt, before a new pre-empt is allowed (see PE's AL
LOWED below)
PRE-EMPTION SET-UP COPES
fer-Trafflt: Control-, ,-Techno/ogies
PRE-EMPTION SEQUENCE STEPS
STEP'" INT MIN MAX HOI JMP V1 V2 V3 V4 V5 COMMENTS
I /0,3 1 e5? ;.10 PcD Ci.R
~ B ':;0 7 1 ( ~I?O"1 )HP/i BRh"'CHIiS :u ~ 'l:bAJ
-3 0/3 LPe BR"''''CHIi S (,;/4 ~ rd1DW)
4 7,;(0
5 -R1'l7
6 901'1 104 4 R ;'d, Yliaol<.!
8 lOS" d. 19 0<(., 45 5:< ,quo Reo 7/011£'" f{P€ B~ANcI/
9 0/5 lPIi 8R~C"€5 (4" R€o)
10 7';':1
II 8411.;( 9+8/3 801 4 t;!,;/ 'I, 12f(., Re#1h'N GRN
/4 8~ .:< /19 <If~ R, 7i-IlE'N vPI To 19
15 803 /0 ';;>0 0 /9 88 88 88 /.pe #1 )./OL1> (1+1.,)
Ito 804· 4 ¢ I r(., Y€L
/1 105 3 Flu.. ReD
/8 99 ReTuRN TO NOR"'"
19 803 /0 .:(0 / 0/10 !-IP€ #' I 1-10(.]:', vMP To 16
,;(0 805 4 ¢~ Y t;!R Re#1I'1"" (-;RN
~I Bob .;? .;;l,).&, ¢/pl(., liIliN Jp.;2 To .:U,
<f(;l 801 10 .:?o '1 91 ':<10 91 91 LP€ IF.:l Jlcx!:> (.;}rS)
t5l3 808 4 (lJ.:JrS YeL
d4 105 .3 /1L<- ReD
':<5 99 ReTURN 70 NoR/VI
0<10 80'1 /0 OlD 0< tJ:J.3 9/ HP€ tt.;l HOLl> , Jmp 70.,:)3
R 8 (; FRO""! .),;<1 31 31 HP€ 8RANc/ollfS 2;" I.SC~
dl8 t.31 LP€ &AHC/oIG.5
019 73130 008 ,: I
31 105 / OM RED REv', .Jmp To 8
3:/ ~/5 1 057 ¢4 Pel:> eLI? Jrnp To 57
3R 39 40 (FROH/ )33 38 }/P~ BRI'/NCJlI?S 3' '? -t'iRN
PRE·EMPTION SEQUENCE STEPS
STEP .. INT MIN MAX HOI JMP Vl V2 va V4 V5 COMMENTS
34 h.:lJ? LPe (FROiVl )8RIlHCH€:; 3~7/::;R'"
35 738
3IP 839
.31 94IP
..38 11.:1 4 008 .3r7 Y","L, 7HEN JNlP Tca
.39 l,Rnq 4 ¢1 )leL, (}5-3 REMJjIN 6RN
40 I RIO ,) 345 ¢7 Reo. vP3 70 45
41 8/1 10 dO ,R 81 81 45 81 LPI! #.3 HOLl> (3r8)
4::< 8/~ 4 ~.3r8 Ye£.
43 /cJ.f ..3 I1LL ReD
44 99 ReT 70 NORN}
45 8/1 /0 .:10 -8 04;1, 81 81 }/P€i1..3 HOL1>. Jmp To 4.:24t, 813 4- ~3 YeL, ¢7 REN7PJ/N GRJoI
47 8/4 e5l 45e5l <13 REI:>, JP4 7i!> 5':<
48 815 (0 c:lo 9 85 85 85 5~ LPG' #4 Ho£.l:> (4 r 7)
49 BlIP 4 ~4+7 YEL
SO /,;/ f ..3 I1LL R€l>Sf 99 R€T 70 NORM
5cJ. 8/5 10 eRo 4 049 85 as 85 HPI!ii4 HOLD. JIYIP 7049
5'3 8 8 5h 5h (FROJ'oll )Hpe B,UINCHE5 3>7 4~8 C<R..
54 t,08 LPC' BRANcl-ies
65 108 LS0 105 I 008 ReD Rev IN)P TO 851 6,;) 6.:J. c.3 d.b HP€ l3R (. FRoN) )
ANCI-I€5 4rBARN
58 t,,,~ Lpl! BRANCHES
59 7~:J.
{,O 8&'3
"I 9"6,;/ I;J,O 4 008 ¢4-r1? YeL Jmp T08
63 8/9 4 ¢4 ye'-I ¢8 REJVlAI'" $IV,",
64 8~0 ~ 345 pi 4 REI:>, JP.3 Tt> 45
65 041 Jmp TO 41 (t..PI! #.3)
{,h 8/1 4 (158 YI! L I (2)10 Re/YJI'lIN GRN
PRE-EMPTION SEQUENCE STEPS
STEP # INT MIN MAX HOI JMP Vl V2 V3 V4 V5 COMMENTS
61 8/h .d 45:( ¢B RCD, JP4 To 5.:J
68 04!? JNlP To 48 (LPE tJ-4)
b9 73 71:> 7~ 7.:J HPI; BR~NCH€:S (I::~n;.;)
70 ~73 LPE 8R~NCH€S
71 77t> (PE BR~HCH€5
7;1 1&8 4 008 ~/ 1'5 Yei.., Jmp To 8
73 8::J! 4 ¢5 YeL, 16/ R€M~o,,6£H
74 8;1~ ,.1 1/9 ¢~ RED, JPI To 19
75 015 Jrnp 70 15 (LPE #/)
7&, 8:13 4- t2l/ YEi.., ¢s REfflRJN (kN
77 8~4- :< .;l~t> ¢I R€D J JP:Z To .,2t>
78 o~,:) Jmp 70 ,;).:2 (LPE #..2)
1t} 8t IN 45 81 ( FRoH7 )J.lP€ Bt<RNCHc5 3rR "GR.N
fit) 841 JP8 (LPE #3) 704{
81 8~5 4 008 3 +8 Y(;/., JIYlP "1'0 8
8~ NoP
83 85 8s 85" 5::J (. Fl?oH7 )HPc BteRJ>/CHES 4107 -GRN
84- 948 JP9 (LP€ #4) To 48
85 8::Jt, 4- 008 4+- 7 )IEL, JfflP To 8
8t, 19 88 88 8B Pi('oH'/ ,,)J.lPE &RNCJ.f€5 (1I-h{:;gN)
81 615 Jpt., ((Pc 4/) To /5
88 8~7 4 008 t+fo YE"I.., JfflP TO 8
89 91 ~ 9/ 9{ (FROh? .)HP€ &~J>/CHE5 ':";5;"D..
90 1dl~ Jp'1 (LP€~) 70 .:2:<'
'}{ 8~8 4 008 ,;:J,.s )IE",-, JrrJP 1b 8
9~ 830 4 5t, ¢4 YE,-, ..)mp TO 5 ~
93 8:Z9 4 5t, ¢8 Yei.., .JfflP To 5~
94 NoP
t:}5 NoP
% 43~ 7 080 ~" Pel:> C'R , JiVlP TO&
91 58:< 1 0??9 ¢.2. P€D C'i?, ,JIVIP 7tJ 89
SECTION XII
LMD40 "N" VERSION
GENERAL
The LMD40N is a software variation of the LMD40 packaged in a chassis with NEMA compatible MSA, B, and CI/O connectors. The chassis is the same as theLMD8000 series.
The major difference between the LMD40N and the standard LMD40 is the I/O configuration. The LMD40 uses aTCT pre-timed MSA, B, and D and the LMD40N usesNEMA MSA, B, and C. The LMD40 MSA and B are notthe same as LMD40N MSA and B. However, most of theprogramming and operation are identical--with the exception of I/O run mode screens (which relate to the pin configurations), and a few functions which are not the same.
The following functions are different:
LMD40 FUNCTIONS NOT IN THE LMD40N:
• Ext CSO
• AZ. Reset
• Added time inhiM
• Sync Inhibtt
• Time clock sync
• Flash Monitor I and 11
• System input
• Cycle 5 input
• Pre-empt 2, 4, 5
• Individual Signal plan select inputs
• System control
• Call to free operation
• User defined 6, 7, 8 (future added to LMD40N)
• Pre-empt 1, 2, 3 clear
• Call to week program 10
• Output 41
• Output 48
• Clk ckts 12 and 13 outputs
LMD40N FUNCTIONS NOT IN THE LMD40:
• Ext Min recall
• I/O Mode Configurations 0-7
• Flashing Logic output
• Coded status Ms A, B, C
• Signal plan 2 and 3 outputs
TS2 type II standard for Pre-timed Controllers
The LMD40N pin configuration and functions have beenassigned with the new NEMA T82 standard in mind.Thus, all available pins have been assigned in accordance with that standard. The optional "mode" configurations are also based on the TS2 standard. Fullcompliance with the T82 standard requires a specialM8A-B-C I/O module which provides circuttry for pinsthat were formerly spares in the T81 standard.
LMD40N PIN-OUT NOTES
The LMD40 pin configuration chart is defined in terms ofthe pin, the LMD40 function for that pin, the NEMA function for that pin, and the mode 1, 2, and 3 functions (seenote 5). The following notes relate to the pin-out configuration.
1. An asterisk In front of the pin letter indicates thatthe LMD40N function is substantially different from theT81 NEMA function. Care should be taken relative tothese functions when retro-fitting a NEMA cabinet with anLMD40N so that unexpected operation does not result.An asterisk under Mode 1, 2, 3 indicates that the functionis non-mode-dependent, i.e. tt is the same as the LMD40function in each of the modes.
12-1
2. The Coded Status Bits will operate as follows in the LMD40N:
Code ABC Description Priority
o OFF OFF OFF MINIMUM TIMING 6
1 ON OFF OFF VARIABLE (AFTER MIN) 7
2 OFF ON OFF HOLD" 8
3 ON ON OFF STOP TIMING 2
4 OFF OFF ON MCE 4
5 ON OFF ON REMOTE FLASH 5
6 OFF ON ON CHECKSUM FAIL 1
7 ON ON ON PRE-EMPT 3
" This code will operate only in a designated hold interval when hold is active and the interval is timed out but holding.
3. "Cycle" and "spur' terminology is used in theLM040N, but TS2 Timing plan inputs and outputsare equivalent to cycle and split inputs and outputswhere:
Cyc2 = TPA
Cyc3 = TPB
Spl2 = TPC
Spl3 = TPO
The selected timing plan is as follows:
12-2
Timing Plan
TPOO
TP 01
TP 02
TP03
TP04
TP05
TP06
TP 07
TP08
TP09
TP 10
TP 11
TP 12
TP 13
TP14
TP15
C2/TPA
OFF
OFF
OFF
OFF
ON
ON
ON
ON
OFF
OFF
OFF
OFF
ON
ON
ON
ON
C3/TPB
OFF
OFF
OFF
OFF
OFF
OFF
OFF
OFF
ON
ON
ON
ON
ON
ON
ON
ON
S2/TPC
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
OFF
ON
S3/TPD
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
OFF
OFF
ON
ON
Reference
C1 S1
C1 S2
C153
C154
C2 S1
C252
C253
C254
C3 51
C3S2
C353
C354
C4 51
C452
C453
C454
4. External min recall places calls on all "C" type intervals.
5. The LMD40N has a number 01 modes in accordance with the TS2 standard. Three time clock circuitshave been provided for mode I/O select bits A, B. and C.The modes resulting from activation of these ckt's are asfollows:
9. To provide options lor up to 8 phase NEMA operation, a number of the NEMA inputs have been softwareOR'ed together and a number of the outputs have beenAND'ed. For example, some of the actuation inputs areOR'D--LMD40N "ACT 5" could be activated by either PH1 PED CALL or PH 5 VEH CALL inputs. Similarly,LMD40N output 13 drives both PH 1 DW as well as PH 5RED. Thus, for each of these dual function pins, one orthe other would be used, but not both.
7. Address bits 0-4 (future) will represent binary encoded addresses 1-32, but only when the comm addressis programmed "0".
No external signal plan slection for signal plands 5-8are provided at this time for the LMD40N. However,signal plans 5-8 can still be selected internally byclock, actuation codes, etc.
MODE A B C DESCRIPTION
0 OFF OFF OFF Basic, no modedependent I/O
ON OFF OFF Hardwire interconnect-secondary
2' OFF ON OFF System Interface
3 ON ON OFF Hardwire interconnect-master
4' OFF OFF ON Reserved
5' ON OFF ON Reserved
6' OFF ON ON Manufacturer specific
7' ON ON ON Manufacturer specific
, Future, not available at this time
6. Signal plan inputs 2, 3, are encoded, which is dif-ferent from the LMD40 which has an input for each signalplan 2-8. The LMD40N signal plan inputs operate as fol-lows:
SIG PLAN
1
2
3
4
SP21N
OFF
ON
OFF
ON
SP31N
OFF
OFF
ON
ON
LMD40 Function
Inputs
ACT 1
ACT 2
ACT 3
ACT 4
ACT 5
ACT 6
ACT 7
ACTa
ACT 9
ACT 10
Outputs
Out 13
Out 14
Out 15
Out 19
Out 20
Out 21
Out 31
Out 32
Out 33
Out 34
Out 35
Out 36
NEMA PIN(S)
Phase 1 veh call
Phase 2 veh call
Phase 3 veh call
Phase 4 veh call
Phase 5 veh callor phase 1 ped call
Phase 6 veh callor phase 2 ped call
Phase 7 veh callor phase 3 veh call
Phase 8 veh call
Phase 4 ped call
Phase 8 ped call
Ph 1 DW and PH 5 Red
Ph 1 PCL and PH 5 Vel
Ph 1 WLK and PH 5 Grn
Ph 3 DW and PH 6 Red
Ph 3 PCL and PH 6 Yel
Ph 3 WLK and PH 6 Grn
OIL C Red and PH 7 Red
OIL C Yel and PH 7 Vel
OIL C Grn and PH 7 Grn
OIL D Red and PH 8 Red
OIL D Vel and PH a Vel
OIL D Grn and PH a Grn
8. Signal Plan 2, 3 outputs represent the selected signal plan 1-4 respectively. None of these outputs are active for signal plans 5- 8.
12-3
MS Connector A LMD40N Pin Termination Assignments:
MODE FUNCTIONSPIN LMD40N FUNCT TS1 NEMA FUNCT MODE 1 MODE 2 MODE 3A Not Used Not Used * * *B +24 VDC +24VDC * * *C Voltage Monitor Voltage Monitor * * *D Out 1 Ph 1 Red * * *E Out 13 Ph 1 Dont Walk * * *F Out 4 Ph 2 Red * * *G Out 16 Ph 2 Dont Walk * * *H Out 17 Ph 2 Ped Clear * * *J Out 18 Ph 2 WALK * * *K ACT 2 Ph 2 veh call * * *L ACT 6 Ph 2 ped call * * *-Note 9*M PE 3 in Ph 2 hold * * *N Stop Timing Stop timing * * *P N/U Inhibit Max R1 * * *R Ext Start Ext Start * * *S Int advance Int advance * * *T N/U N/U * * *U AC- AC- * * *V Earth ground Earth ground * * *W Logic ground Logic ground * * *X Flashing logic Flashing Logic * * *Y Status Bit C Status bit C * * *-Note 9
Z Out 2 Ph 1 Yellow * * *a Out 14 Ph 1 Ped Clear * * *
b OutS Ph 2 Yellow * * *
c Out 6 Ph 2 Green * * *
*d Flash attained Ph 2 check * * *
*e Out 44/Cyc3 out Ph 2 phase on Out 44 Out 44 Cyc 3 out
f ACT 1 Ph 1 veh call * * *
g ACTS Ph 1 ped call * * *-Note 9
*h PE 1 in Ph 1 hold * * *
Force off Force off * * *
j Ext recall Ext recall * * *-Note 4
k MCE MCE * * *
m N/U CNAI * * *
n N/U TestA * * *
P AC+ AC+ * * *
q N/U N/U * * *
r Status bit B Status bit B * * *-Note 2
12-4
MS Connector A LMD40N Pin Termination Assignments (continued):
MODE FUNCTIONS
PIN LMD40N FUNCT TS1 NEMA FUNCT MODE 1 MODE 2 MODE 3
s Out 3 Ph 1 Green " " "OU115 Ph 1 Walk " " "
"u Offset 3 oU1 Ph 1 check N/U N/U Off 3 oU1
"v Remote Flash Ph 2 ped omtt " " "w N/U Omit red clear Rl " " "x N/U Red rest mode R1 " " "y N/U N/U " " "z N/U CNA II " " "AA N/U Test B " " "BB N/U Walk rest modify " " "CC Status btt A Status bit A " " ""DO Out 42/Cyc2 out Ph 1 phase on Out 42 Out 42 Cyc 2 out
"EE Dim inpU1 Ph 1 ped omtt " " "FF N/U Ped recycle Rl " " "GG N/U Max II select " " "HH N/U N/U " " "
12-5
MS Connector B LMD40N Pin Termination Assignments:
MODE FUNCTIONS
PIN LMD40N FUNCT TS1 NEMA FUNCT MODE 1 MODE 2 MODE 3
*A Out 43/SPL2 out Ph 1 phase next Out 43 Out 43 SPLT 2 outB N/U N/U * * **C OU1 45/SPL3 oU1 Ph 2 phase next OU145 OU145 SPLT 3 oU1D OU19 Ph 3 Green * * *E OU1a Ph 3 Yellow * * *F Out? Ph 3 Red * * *
G Out10 Ph 4 Red * * *H Out 23 Ph 4 Ped Clear * * *
J Out 22 Ph 4 Dont Walk * * *
*K Sig plan 3 out Ph 4 check N/U N/U SP3 out
L ACT 4 Ph 4 veh call * * *M ACT 9 Ph 4 ped call * * *N ACT 3 Ph 3 veh call * * *P ACT? Ph 3 ped call * * *-Note 9
*R Splt2/Sdet 5 Ph 3 omit Spit 2 in Sys det 5 Spit 2 in
*S Sys det 4 Ph 2 omit N/A Sys det4 N/A
*T Off 1 in/Addr 2 Ph 5 ped omit Off 1 in Addr2 Off 1 in
*U Sys det 3 Ph 1 omit N/U Sys det 3 N/U
V N/U Ped recycle R2 * * *
W N/U N/U * * *
X N/U N/U * * *
Y Out 21 Ph3Waik * * *
Z Out 20 Ph 3 Ped Clear * * *
a Out 19 Ph 3 Dont Walk * * *
b Out 12 Ph 4 Green * * *
c Out 11 Ph 4 Yellow * * *
d Out 24 Ph 4 Walk * * *
*e Clk ckt 10 Ph 4 phase on * * *
*1 Out4?/0ff2 oU1 Ph 4 phase next OU14? OU14? Off 2 oU1
*g Splt3 in/Sdet 6 Ph 4 omit Spit 3 in Sys det 6 Spit 3 in
*h SP3 in/Sdet 2 Ph 4 hold SP3 in Sys det 2 SP3 in
*1 SP2 in/Sdet 1 Ph 3 hold SP2 in Sys det 1 SP2 in
*j Cyc2 in/Addr 0 Ph 3 ped omit Cyc 2 in AddrO Cyc2 in
*k Off 2 in/Addr 3 Ph 6 ped omit Off 2 in Addr3 Off 2 in
*m Off 3 in/Addr 4 Ph? ped omit Off 3 in Addr4 Off 3 in
*n Int Inhibit Ph a ped omit Int Inh N/U Int Inh
p OU126 O/L A Yellow * * *
q OU125 O/LA Red * * *
*r Clk 11 /SP2 oU1 Ph 3 check Ckt 11 Ckt 11 SP20U1
12-6
MS Connector B LMD40N Pin Termination Assignments (continued):
MODE FUNCTIONS
PIN lMD40N FUNCT TS1 NEMA FUNCT MODE 1 MODE 2 MODE 3
*s Clk ckt 9 Ph 3 phase on * * *
*t Out 46/Off 1 out Ph 3 phase next Out 46 Out 46 Off1 out
u Out 34 Oil 0 Red * * *-Note 9
v N/U N/U * * *
w Out 36 Oil 0 Green * * *-Note 9
x Cyc 3 in/Addr 1 Ph 4 ped omtt Cyc3 in Addr1 Cyc3 in
y N/U N/U * * *
z N/U Max 11 select R2 * * *
AA Out 27 Oil A Green * * *
BB Out 29 Oil BYeliow * * *
CC Out 28 Oil B Red * * *
DO Out 31 O/lC Red * * *-Note 9
EE Out 35 Oil oYellow * * *-Note 9
FF Out 33 O/lC Green * * *-Note 9
GG Out 30 Oil B Green * * *
HH Out 32 011 CYeliow * * *-Note 9
12-7
MS Connector C LMD40N Pin Termination Assignments:
MODE FUNCTIONS
PIN LMD40N FUNCT TSl NEMA FUNCT MODEl MODE 2 MODE 3A N/U Status bn A (R2) " " "B N/U Status bk B (R2) " " "C Out 39 Ph 8 Dont Walk " " "D Out 34 Ph 8 Red " " "-Note 9E Out 32 Ph 7 Yellow " " "-Note 9F Out 31 Ph 7 Red " " "-Note 9
G Out 19 Ph6 Red " " "-Note 9
H Out 13 Ph 5 Red " " "-Note 9
J Out 14 Ph 5 Yellow " " "-Note 9
K NN Ph 5 Ped Clear " " "L N/U Ph 5 Dont Walk " " "M N/U Ph 5 phase next " " "N N/U Ph 5 phase on " " "P ACTS Ph 5 veh call " " "-Note 9
R N/U Ph 5 ped call " " "S ACT 6 Ph 6 veh call " " "-Note 9
T N/U Ph 6 ped call " " "U N/U Ph 7 ped call " " "V ACT 7 Ph 7 veh call " " "-Note 9
W ACT 10 Ph 8 ped call " " "X NN Ph 8 hold " " "Y N/U Force off R2 " " "Z N/U Stop Time R2 " " "a N/U Inhibit Max R2 " " "b N/U N/U " " "c N/U Status bit C (R2) " " "d Out 40 Ph 8 Walk " " "-Note 9
e Out 35 Ph 8 Yellow " " "-Note 9
f Out 33 Ph 7 Green " " "-Note 9
9 Out 21 Ph 6 Green " " "-Note 9
h Out 20 Ph 6 Yellow " " "-Note 9
Out 15 Ph 5 Green " " "-Note 9
j N/U PhS Walk " " "k N/U Ph 5 check " " "m N/U Ph 5 hold " " "n NN Ph 5 omit " " "p Hold Ph 6 hold " " "q N/U Ph 6 omit " " "
N/U Ph 7 omit " " "r
12-8
MS Connector C LMD40N Pin Termination Assignments (continued):
MODE FUNCTIONS
PIN LMD40N FUNCT TS1 NEMA FUNCT MODE 1 MODE 2 MODE 3
s N/U Ph 8 omit • • •t ACT 8 Ph 8 veh call • • ·-Note 9u N/U Red rest R2 • • •v N/U Omit red clear R2 • • •w N/U Ph 8 Ped Clear • • •x Out 36 Ph 8 Green • • ··Note 9
y N/U Ph 7 Dont Walk • • •z Out 37 Ph 6 Dont Walk • • ··Note 9
AA N/U Ph 6 Pad Clear • • •BB N/U Ph 6 check • • •CC N/U Ph 6 phase on • • •DD N/U Ph 6 phase next • • •EE N/U Ph 7 hold • • •FF N/U Ph 8 check • • •GG N/U Ph 8 phase on • • •HH N/U Ph 8 phase next • • •JJ N/U Ph 7 Walk • • •KK N/U Ph 7 Pad Clear • • •LL Out 38 Ph 6 Walk • • ·-Note 9
MM N/U Ph 7 check • • •NN N/U Ph 7 phase on • • •PP N/U Ph 7 phase next • • •
12-9
NOTES:
SECTION XIII
MAINTENANCE
Surface Mount Technology
SOCKET MOUNTED OPERATINGSOFTWARE PROMS
INTEGRATED CIRCUIT REMOVAL & REPLACEMENT
The LMD40 PROMS can be replaced when a revisionupgrade is required. The socket positions are labeled onthe PROMs, be sure to place them in the correct positionand right side up. Also, check to be sure the upgrade iscompatible with your existing programmed data.
Tweezers
Small tip soldering iron
Temperature indicating lacquer
Braided solder wick
Solder paste syringe dispenser
RMA flux
Hot air repair station
Heat shields
•
•
•
•
••
••
An IC is not a discrete component but a functional circuit(or circuits) within itself. Furthermore, since an IC cannotbe repaired it is only necessary to determine:
(1) That the IC is defective, generally by replacementone known to be good.
(2) That the defect was not caused by some other circuit malfunction. If it has been shown definitely that anIC is defective it must be replaced.
The LMD controller predominantly uses surface mountedIC components. Although this technology providesbenefits in reliability, size, and performance, it does require different 1echniques in removing and replacingthese components. The following is a list of what is required as a minimum to repair surface mount equipment:
Manual Station
This work station is the minimum required and would consist of a well lighted work area, grounded to preventstatic electricity damage to the electronic components,and a set of tools similar to the list below.
LMD CHECK-OUT
INTERNAL DIAGNOSTICS
The LMD40 has an Internal diagnostic routine as part ofthe standard operating software. Activation and operation of the internal diagnostic routine is described in the"LMD Diagnostic Test Specification", TDB 154, which canbe ordered from your distributor or from TCT. Pleasenote that the internal diagnostic routine is not intendedas a field troubleshooting procedure, but as a shop test.A special cable (0807460) is required and the outputsand indications do not operate normally. Also, once executed, the LMD40 must be restarted to exit the diagnostic routine.
The LMD controller, if faulty, should be removed from thecabinet and replaced wtth a known good untt. When substttuting wtth a replacement unit, it Is generally easiest toremove the Information Memory Card (IMC) from the faulty unit and insert it Into the replacement unit. This willautomatically transfer the programmed data and realtime into the new untt upon power-up.
Power On Self Test (POST) will reveal potential failureson the (IMC) card itself, however, to check for datafailures, go to the Run Mode Menu/Checksum Status toverify there are no checksum failures. Also, it Is recommended that the records of the controller data be kept inthe shop as well as in the field.
To access the LMD circuitry, fold down the front panelafter loosening the two top thumbscrews. This will expose all boards, which are fastened by retaining clips.The Information Memory Card (IMC) is the small board inserted perpendiculariy into the control board. To removeit, bend back the retaining clip at the top and gently slideit off the post. The board is now free to remove from theedge connector. Remove any other boards in a similarmanner, while removing any ribbon cables or internal harness connectors.
FOLD DOWN PANEL
13-1
Several sizes of tweezers will be required to handle thesmallest packages and chip capacttors all the way up tothe 84 pin PLCC (Plastic Leaded Chip Carrier). Somesoldering irons have special de-soldering tips that can beused for almost all small SMC's in addition to standardsoldering tips. Also, there are individual de-solderingtools that appear to be the equivalent of "hot tweezers"that are designed to remove a specffic size of SMC.
Temperature indicating lacquers are useful for saferemoval of a defective component. A temperature on thelow side (184 oC) is preferable, as the body heats a littleslower than the leads. The braided solder wick is a standard ttem sold by several electronic hobby shops.
Bench Repair
The major procedure needed in the field is the ability toremove and replace a defective component. The toolslisted under the manual station will be necessary. Thebest procedure to follow for removal and replacement islisted below. Step 11 would be accomplished by usingthe repair station with due care to monitor the solderreflow, removing the heat immediately after the solderhas achieved a thorough reflow. In an emergency situation, a component can be attached by using tweezers,soldering iron, and solder paste. Careful application ofheat and solder is still the important issue. Clean-up canbe achieved by using an aerosol spray can of appropriate solvent.
Procedure
1. Correctly identify the defective component.
2. Paint a small amount of temperature sensitive lacquer on the defective component.
3. Set up the repair station and adjust the temperature controls according to board size and component mass.
4. Place the board on the repair station, centeringthe component under the hot air outlet.
5. Place a heat shield over the adjacent componentsor place the vacuum collet on the defective component.
6. Begin applying heat.
7. When the temperature sensitive lacquer gives apositive indication, remove the untt wtth tweezersand remove hot air from board. With the semiautomatic station, the vacuum collet will lift the unttand redirect the hot air.
8. The footprint must now be cleaned of excesssolder with a soldering iron and solder wick toachieve smooth, planar lands.
13-2
9. Use the solder syringe dispenser to put a properand even amount of solder paste on each component land.
10. Place the component with care to get tt correctlyaligned.
11. Reflow and clean by using the reflow and cleanup equipment.
SCHEMATIC and ASSEMBLY DRAWINGS
Schematic drawings and sub-assembly drawings havebeen provided for all major boards and assemblies wtthinthe LMD40 series untt.
Assembly Drawing Description
0807426 ND LMD40 Controller
0807455 ND LMD40 "N" version controller
Schematic Drawing Description
0807391 Power Supply Board
0807381 (shts 1 and 2) Control Board
0807421 (shts 1-3) Input/Output Board
0807397 Communications Board
0807384 LMD40"N" (shts 1 and 2) Input/Output Board
Sub Assembly Description
0807393 S/A Power Supply Board
0807418 S/A Control Board
0807389 S/A EEPROM/RTC Board
0807173 S/A Display Module
0807423 (shts 1 and 2) S/A I/O Board
0807399 S/A Communications Board
0807172 S/A Transformer Harness
0807386 LMD40"N" (shts 1 and 2) S/A I/O Board
Parts Lists
Parts lists have been provided for most component partsincluding TCT's part number as well as themanufacturer's part number. Most are available fromstandard electronic supply houses, except for thosespecffied as TCT only. For those listed by othermanufacturer's please exercise caution when obtaining"substttute" or "equivalent" parts other than the part andmanufacturer listed. Suffice it to say that all parts are notcreated equal. The des;gn characteristics and performance of individual parts do make a difference, and wedo choose specific parts from specffic manufacturers fora reason. When in doubt, consult your distributor or TeT.
PARTS LIST POWER SUPPLY BOARD S/A 0807393
Reference TeTSymbol Description Comp Mfr's Part Number Part Number
Integrated Circuits
RNl RES. NETWORK-lOOK, 71S0 BOURNS 4114R-Q01-l 04 020A86-136RN2 RES. NETWORK-10K, 81S0 BOURNS 4116R-Q01-l03 020A87-112Ul,2 PULSE WIDTH MODULATION CKT. MOTOROLA MC34060A 121H43-DOlU3,4,S ~UAD CAOMPARATOR/BUFFER MOTOROLA MC33302P 021 Kll-QOlU6 VOLTAGE CONVERTER W/REG. LINEAR TECH LT10S4N8 121K18-QOl
Transistors
01,6,11,14 TRANSISTOR-AMPLIFIER, NPN MOTOROLA MPSA06 120E3S-QOl02,8,10 TRANSISTOR-AMPLIFIER, PNP MOTOROLA MPSA56 120E34-QOl03,9 TRANSISTOR-POWER MOTOROLA MJEl6004 120E43-00104,7,12 TRANSISTOR-DARLINGTON MOTOROLA MPSA28 120E33-QOlOS,13 TRANSISTOR-DARLINGTON T.I. TIP120 120ES4-QOl
Capacitors
Cl,2,8,13,lS,17, CAP..1 ufd, SOY, 20%, CER AVX SA30SC104MAA18,19,2S,30,32,39C3 CAP. 2700 ufd, 7.SV, -10+100%, AE SPRAGUE 672D278H7RSFVSCC4,S,10,ll CAP..01 ufd, 100V, 10%, CERAMIC AVXSA201Cl03KAAC6,16,21,26,33 CAP..1 ufd, 100V, 20%, CERAMIC AVX SA401Cl04MAAC7,14,20,22,27 CAP. 4.7 ufd, 20V, 10%, TANTALUM MALLORY TAC47SK020P02C9,12, CAP. 1000 pfd, 100V, 10%, CER. AVX SA201Al02KAAC23,28,31 CAP..27 ufd, SOY, 10%, TANT SPRAGUE 173D274X90S0UC24,29 CAP. 820 ufd, 40V,-10 + 100%, AL.E. SPRAGUE 672D827H040FVSCC34 CAP. 17,000 ufd, 7SV, -10 + 7S%, SPRAGUE 36DE173G07SBCSLC3S,36 CAP. 1 ufd, 3SV, 20%, TANTALUM UNION CARB. T322Bl0SM03SASC37 CAP. 22 ufd, 20V, 10%, TANTALUM UNION CARB. T322D226K020ASC38 CAP. 470 ufd, 20V,-10 + 100%, AL.EL SPRAGUE 672D477H020EKSC
Diodes
120C29-104
120C62-278020C2S-103120C36-104120D9S-47S020C2S-102020D96-274120C65-827120C72-179020D86-10S12009S-226120G69-477
CRlCR2,9CR3,12CR4CRS,6,10,lS,16,18,22,23,2SCR7,8,llCR13CR14CR17,20,21 ,24CR19
Inductors
L2,3L1
DIODE - ZENER, 7.SV, lWDIODE - RECTIFIER, 4ADIODE - ZENER, 33V, lWDIODE - ZENER, 24V, lWDIODE - RECTIFIER, lA
DIODE - SIGNALDIODE - ZENER, 7.S V, SWDIODE - ZENER, 6.8V, SOOmWDIODE - RECTIFIER, SADIODE - ZENER, 13V, lW
INDUCTOR, 2S0uhINDUCTOR, .33uh
1N4737AMUR410lN47S2AlN4749AlN400S
lN41481NS343B1NS23SB1NS62S1N4743A
DALE IH-3 2S0 uhDALE IM-4 .33 20%
020F28-4737120W30-QOl020F28-47S2020F28-4749120W3S-400S
120F07-001120F30-S343020F27-S23S020W49-QOl120F28-4743
120J30-QOl120J2S-QOl
13-3
ReferenceSymbol
Resistors
Description Comp Mfr's Part NumberTCT
Part Number
RES..1 OHM, lW, 5%, MET. OXIDE -RES. 220 OHM, 1/4W, 5%, CARBON --
RES. 33K, 1/4W, 5%, CARBONRES. 620 OHM, 1/4W, 5%, CARBON -RES. 9.1K, 1/4W, 5% CARBONRES. 1M, 1/4W, 5%, CARBONRES. 39K, 1/4W, 5%, CARBONRES. 5.1 OHM, 1/4W, 5%, CARBON -RES. 4.7K, 1/2W, 1%, CARBONRES. 1K, 1/4W, 5%, CARBON
Rl,10,30,35,38 RES. 3.9K, 1/4W, 5%, CARBON58,66,72R2,59R3,8, 19,31,34,36,45,46R4,7,15,18,67R5,12,26,41R6,9R",14R13,25R16,48R17,5OR20,32,43,55,57,69,74R21,24,33,37,42, RES. 10K, 1/4W, 5%, CARBON44,52,53,64,70,80R22,23 RES. 68 OHM, 1/4W, 5%, CARBON --R27 RES. 2740 OHM, 1/2W, 1%, GTOR28,79 RES. 732 OHM, 1/2W, 1%, GTOR29,40,49,63 RES. 47K, 1/4W, 5%, CARBONR39 RES. 62K, 1/4W, 5%, CARBONR47,65,68,71 RES. lOOK, 1/4W, 5%, CARBONR50,56 RES. 240K, 1/4W, 5%, CARBONR51 RES. 330K, 1/4W, 5%, CARBONR54 RES. 30K, 1/4W, 5%, CARBONR61,62 RES. 2.40HM, 5W, 5%, WIRE WND --R73 RES. 12K, 1/4W, 5%, CARBONR75 RES. 100 OHM, 1/4W, 5%, CARBON --R76 RES. 2.1K, 1/2W, 1%, GTOR77,78 RES. 243 OHM, 1/2W, 1%, GTO
Miscellaneous
020A01-102
120A59-340020A01-D72
020AOl-124020A01-D83020A01-111020AOl-15O020A01-D83020A01-D33020A04-104020A01-D88
020AOl-112
020A01-D59020A44-D98020A44-272020AOI-128020AOl-131020AOl-136020AOI-145020A01·148020AOl-123020A24-D25020AOl-114020A01-D64020A44-275020A44-271
Fl,F2Fl,F2J2,J3MOV1,2030903,9VRlVR2,3
13-4
FUSE - 1 AMP, SLO-BLOFUSEHOLDER & CAPRECEPTACLE - 4 POSITIONVARISTORHEAT SINKHEAT SINKINSULATORINVERTERREGULATORPRINTED CIRCUIT BOARD (only)
L1TILEFUSE 313000 SERIESL1TLEFUSE 345-101AMP 640499-1GE V150LA10ATHERMALLOY 5073PB-SE-lTHERMALLOY 5072BSE-3/1THERMALLOY 53-77-2ENDICOTI RESEARCH LPS24-2-1NATIONAL LM317TTCTONLY
020T41-100120V59-D01021R71-D04020L21-OO1020T30-D01120T08-OO1120T06-220120E64-D01021 K06-D010807392-CM-1 &2
PARTS LIST S/A, CONTROL BOARD 0807418
Reference TCTSymbol Description Compo Mfr's Part Number Part Number
Integrated Circuns
RN1,2 RESISTOR NETWORK, 10K CTS of BERNE 767-161R10K 121 E50-112U1,2 OCTAL D-TYPE FLIP-FLOP NATIONAL MM74HC574WM 121 F30.o01U3 2280 MICROPROCESSOR ZILOG Z8028010VSC REV J 121F51.o01U4,20 HEX INVERTER NATIONAL MM74HC04M 121F11.o01U5,21 TRIPLE 3-INPUT NOR GATE NATIONAL MM74HC27M 121F12-D01U6,7,8 QUAD 2-INPUT OR GATE NATIONAL MM74HC32M 121F14.o01U10 PLD PROGRAMMED AMD-AMPAL16L8WC/PGM7401 121F76-D01U11,19 8 INPUT NAND GATE NATIONAL MM74HC30M 121 F13.o01U12 12 STAGE BINARY COUNTER NATIONAL MM74HC4040M 121F46.o01U13 QUAD ANALOG SWITCH RCA CD74HC4066M 121 F47.o01U14,15 3 TO 8 LINE DECODER NATIONAL MM74HC138M 121 F20.o01U16 DUAL MONOSTABLE VIBRATOR NATIONAL MM74HC123AM 121F17.o01U17 OCTAL BUS TRANSCEIVER NATIONAL MM74HC245AWM 121F26.o01U18 OCTAL BUS BUFFER NATIONAL MM74HC244WM 121F25.o01U22,23,27,28 PROM, UNPROG, 64K X 8 BIT ATMEL AT27C512R-20DC 121K65-D01U22,23,27,28 PROM SET, LMD40 TCTONLY 0807427U22,23,27,28 PROM SET, LMD40N TCT ONLY 0807497U24,29 STATIC RAM, 8192 X 8 BIT ATMEL AT3864L-15RC 121F77-D01
Gapacnors
C1·10,18-21, CAP..1ufd, 50V, +80%, -20% CER. M.E. (MURATA-ERIE NORTH AM) 121 C01-1 0425,26,28,31,36 GRM42-6Y5V104Z050BDC23,24 CAP. 22 pfd, 50V, 5%, CERAMIC M.E. GRM42-6CDG220J050BL 121C03-220C17,22,27 CAP..01ufd, 50V, 10%, CERAMIC M.E. GRM42-6X7R103K50V 121C02·103C29,30 CAP. 4.7 ufd, 20V, 10%, TANT. MEPCO/CEN49MC475C020KOASFT121C25-475
Diodes
CR1 DIODE 1N4005 AMPEREX BYD17J 121 D5O-4005CR2 DIODE 1N4148 AMPEREX PMLL4148 121001-4148
Resistors
R1 RES, 120K, 1/4W, 5%, CARBON KOA SPEER RM73B2BT124J 121E02-138R2 RES, 5.6K, 1/4W, 5%, CARBON KOA SPEER RM73B2BT562J 121 E02-1 06R3 RES, 10 OHM, 1/4W, 5%, CARBON KOA SPEER RM73B2BT100J 121 E02.o40R4 RES, 430 OHM. 1/4W, 5%, CARBON KOA SPEER RM73B2BT431J 121 E02.o79R5-8 RES, 2.7K, 1/4W, 5%, CARBON KOA SPEER RM73B2BT272J 121 E02.o98R16 RES, 10K, 1/4W, 5%, CARBON KOA SPEER RM73B2BT103J 121E02·112
Miscellaneous
J1 HEADER - DOUBLE ROW, 16 PIN AMP 102973-8 120P33.o16J2,J3 HEADER· DOUBLE ROW, 40 PIN AMP 2-102973.0 120P33.o40J6 CONNECTOR, EDGE, 36 POS. AMP 1-530844-5 120R42.o36Y2 CRYSTAL -19.6608 MHZ M-TRON MPI19.6608 120G02.o09U22,23,27,28 SOCKET - 28 PIN AMP 641873-1 020V90.o28
PRINTED CIRCUIT BOARD TCTONLY 0807382
13-5
PARTS LIST S/A, INFORMATION MEMORY CARD 0807389
M.E. GRM42-6Y5Vl04Z050BD 121C01-l04JOHANSON 9614 020C30-Q01M.E. GRM42-6CDG220J050BL 121C03-220MEPCO/CEN49MC475C020KOASFT121 C25-475
RES, 2.7K, 1/4W, 5%, CARBON KOA SPEER RM73B2BT272JRES, 10K, 1/4W, 5%, CARBON KOA SPEER RM73B2BT103JRES, 430 OHM. 1/4W, 5%, CARBON KOA SPEER RM73B2BT431J
ReferenceSymbol
Integrated Circuits
U9U26,31U32U33,34
Capac~ors
Cll,12,28,37,38C15C16C34,35
Diodes
CR4
Resistors
R9,10,11R14,17R15
Miscellaneous
B2Yl
13-6
Description
REAL TIME CLOCKEEPROM, 64K CMOSQUAD ANALOG SWITCHOCTAL D TYPE FLIP FLOP
CAP..1ufd, 50V, +80/-20% CER.CAP. 7-40 pfd, 250V, CERAMICCAP. 22 pfd, 50V, 5%, CERAMICCAP. 4.7 ufd, 20V, 10%, TANT.
DIODE lN4148
BATIERY - NICAD, 2.4VCRYSTAL - 32,768 KHZPRINTED CIRCUIT BOARD
Compo Mfr's Part Number
NATIONAL MM58274CVATMEL AT28C64-20JCRCA CD74HC4066MNATIONAL MM74HC574WM
AMPEREX PMLL4148
GE41B017AC01101STATEK CX-W 32.768 KHZ ATCTONLY
TCTPart Number
121F60-oDl121F78-QOl121F47-QOl121F30-QOl
121001-4148
121 E02-Q98121 E02-112121 E02-Q79
021 G02-QOl020G03-QOl0807388
PARTS LIST SIA, I/O BOARD 0807423
Reference TCTSymbol Description Compo Mfr's part number Part Number
Integrated Circuits
RNl RES. NET., 330K, 8 ISO. DIP CTS of BERNE 767-163R330K 121E51-148RN2,3,4 RES. NET., 68K, 15 COM. DIP CTS of BERNE 767-161R68K 121E50-132RN5-10,12,13, RES. NET., 10K, 15 COM. DIP CTS of BERNE 767-161Rl0K 121E50-112RNll,14-16,21 ,22 RES. NET., 220K, 8 ISO. DIP CTS of BERNE 767-163R220K 121E51·144RN17-20,23Ul OPERATIONAL AMPLIFIER MOTOROLA C1741CD 121F52-QOlU2-7,12-16 DARLINGTON TRANS. ARRAY SPRAGUE ULN2003L 121 F50-QOlU8-11 GATE ARRAY (CUSTOM) TCT7145 TCTONLY 121FOl-7145U17-21 ,28-35 PHOTOTRANSISTOR, OPTO-ISO. MOTOROLA MOC211 121F55-QOlU22 QUAD LINE RECEIVER SIGNETICS MC1489AD 121F54-QOlU23 QUAD LINE DRIVER SIGNETICS MC1488D 121 F53-QOlU24 QUAD 2-INPUT OR GATE NATIONAL MM74HC32M 121F14-QOlU25 HEX INVERTER NATIONAL MM74HC04M 121Fll-QOlU26 3 TO 8 LINE DECODER NATIONAL MM74HC138M 121 F20-QOlU27 OCTAL D-TYPE FLIP-FLOP NATIONAL MM74HC374WM 121F28-QOl
Capacitors
Cl ,2,5,6,13,14, CAP. 0.33 ufd, 35V, TANT MEPCO/ELECT49MC334A035KOAS 121 C26-334C21,22,57-61C3,4,7-12,15-20 CAP. 0.1 ufd, 50V, CER. M.E. GRM42-6Y5Vl04Z050BD 121C01-l04C23-55,62,64-66C67-73C56 CAP. 4.7 ufd, 20V, TANT MEPCO/CEN49MC475C020KOASFT121 C25-475C63 CAP..01 ufd, 50V, CER M.E. GRM42-6X7Rl02K50V 121C02-102
Diodes
CRl DIODE-ZENER IN4752A THOMSON BZM 85 C 33 121025-4752CR2,4-8,9-16 DIODE, IN4005 AMPEREX BYD17J 121050-4005CR3 DIODE,IN4148 AMPEREX PMLL4148 121001·4148CR17 DIODE·ZENER lW, 82V THOMSON BZM 85 C 82 121025-4762
Resistors
Rl,5,6 RES. 68K, 1/4W, +/-5% CARBON KOA SPEER RM73B2BT683J 121E02·132R2,10,24,26,28 RES. 10K, 1/4W, +/-5% CARBON KOA SPEER RM73B2BT103J 121E02·112R30,32,38R3 RES. 3.01K, 1/4W, +/·1% CARBON KOA SPEER RK73H2B-F3.01 K 121E06-277R4 RES. 68.1K, 1/4W, +/-1% CARBON KOA SPEER RK73H2B-F68.1 K 121 E06-343
R7 RES. 34K, 1/4W, +/-1% CARBON KOA SPEER RK73H2B-F34.0K 121 E06-328R8 RES. 17.4K, 1/4W, +/-1% CARBON KOA SPEER RK73H2B-F17.4K 121E06-342R9 RES. 8.66K, 1/4W, +/-1% CARBON KOA SPEER RK73H2B-F8.66K 121 E06-341Rll-18,23,25,27 RES. 20K, 1/2W, +/-5% CARBON KOA SPEER RM73B2HTE203J 121E04-119R29,31R19-22,51 RES. lK, 1/4W, +/-5% CARBON KOA SPEER RM73B2BT102J 121 E02-Q88
R33-37 RES. 330K, 1/4W, 5% CARBON KOA SPEER RM73B2BT334J 121 E02-148
R39-50 RES. 220, 1/4W, + /-5%CARBON KOA SPEER RM73B2BT220J 121 E02-Q72
13-7
PARTS LIST S/A, I/O BOARD 0807423
ReferenceSymbol
Miscellaneous
Description Compo Mfr's part numberTCT
Part Number
MSAMSBMSD
J1J2J3J4
13-8
CONNNECTOR, 55 POS.CONNNECTOR, 19 POS.RECEPTACLE, 63 PINPRINTED CIRCUIT BOARDCONNECTOR-EDGE, 36 POS.CONNECTOR, 40 POS.HEADER-RT.ANGLE, 12 POS.CONNECTOR, D-TYPE, 25 POS.
lIT CANNON KPT 45528-415 SPCL 120R70-Q55SOURIAU B51-Q2E14-19P50-A7 120R73-Q19AMP 206455-2 021 R61-oD1TCT ONLY 0807422AMP 1-530844-4 120R42-Q36AMP 86418-2 020R29-Q4OAMP 1-87233-2 120P35-Q12AMP 745187-6 120R57-Q25D
PARTS LIST COMMUNICATIONS BOARD S/A 0807399
Reference TCTSymbol Description Comp Mfr's Part Number Part Number
Integrated Circuits
RN1,5 RES. NETWORK-10K, 15 COM CTS of BERNE 761-1-R10K 20A82-112RN2,4 RES. NETWORK-220K, 10 ISO CTS of BERNE 761-3-R220K 20A87-144RN3 RES. NETWORK-{)8K, 15 COM CTS of BERNE 761-1-R68K 20A82-132U1 OPERATIONAL AMPLIFIER RAYTHEON RV4559NB 121J84-Q01U2 FSKMODEM AMD AM7911 PC 121 K36-Q01U3,4,7 OCTAL D-TYPE FLIP/FLOP T.I. SN74HC574 121J09-Q01U5,8 DECODER 3 TO 8 LINE NATIONAL MM74HC138N 121J06-Q01U9 DUAL D-TYPE F/F W/CLEAR NATIONAL MM74HC74N 121 HGG-Q01U10 SCC SERIAL COM. CONTR. ZILOG Z803006PSC 121J19-Q11U11 QUAD LINE DRIVER SIGNETICS MC1488N 121JOO-Q01U12 QUAD LINE RECEIVER T.I. MC1489N 121J97-Q01
Transistors
Q1,3 TRANSISTOR MOTOROLA MPAS06 120E35-Q01Q2 TRANSISTOR MOTOROLA MPSA56 120E34-Q01
Capacitors
C1,3 CAP. 2.2 ufd, 35V,10% TANT. UNION CARBIDE T322 SERIES 20C35-225C2 CAP. 2200 pfd, 100V, 10% CER. CORNING CAC03COG222K050A 120C37-222C4-21 ,23-26,28 CAP. 0.1 ufd , 50V, 20% CER. CORNING CAC04X7R104M050A 120C29-10432,34,37C27,33 CAP. 22 ufd, 20V, 10% TANT. UNION CARB. T322D226K020AS 120D95-226C31,36 CAP. 4.7 ufd, 20V ,10% TANT. MALLORY TAC475K020P02 120D95-475
Diodes
CR1,2 DIODE - ZENER, 9.1 V In SEMICONDUCTOR 1N5239B 020F27-5239CR3,4 DIODE - ZENER, 4.7V In SEMICONDUCTOR 1N5230B 020F27·5230CR5 DIODE - ZENER, 5.1V In SEMICONDUCTOR 1N5231 B 020F27-5231CR6 DIODE - ZENER, 12V FAIRCHILD 1N4742A 120F28-4742CR7 DIODE - RECTIFIER GENERAL INSTRUMENTS 1N4005 120W35-4005
Resistors
R1 RES. 240 OHM, 1W, 5% 20A06-Q73R2,10 RES. 560 OHM ,1/4W, 5% 20A01-Q82R3,4,7,11 RES. 22K, 1/4W, 5% 20A01-120R5 RES. 9.1K, 1/4W, 5% 20A01-111
R8 RES. 62 OHM, 1/4W , 5% 20A01-Q59
R9 RES. 620 , 1/4W , 5% 20A01-Q83
R12 RES. 100K, 1/4W ,5% 20A01-136
R13 RES. 820, 1/4W, 5% 20A01-Q86
R14,18,24,25 RES. 10K, 1/4W, 5% 20A01-112
R15 RES. 2.2K, 1/4W, 5% 20A01-QOO
R16 RES. 3.3K, 1/4W, 5% 20A01-100
R17 RES. 5.6K, 1/4W, 5% 20A01-106
R19 RES. 24K, 1/4W ,5% 20A01-121
R20 RES. 240 OHM, 1/2W , 5% 20A04-Q73
R23 RES.1.2K, 1/4W, 5% 20A01-Q90
R26 RES.3.9K, 1/4W , 5% 20A01-102
13-9
ReferenceSymbol
Miscellaneous
J1J2J4,7-11,13,14J5J6J12J15T1,2
Description
CONNECTOR - D - TYPE 9 POS.CONNECTOR - D - TYPE 15 POS.JUMPER-WIRE INSUu\TEDHEADER SINGLE ROW 3 POS.HEADER-D/ROW 12 POS.EDGE CONNECTOR, 90', 36 POS.CONNECTOR, D TYPE, 25 POS.TRANSFORMERPRINTED CIRCUIT BOARD (only)
Comp Mfr's Part Number
AMP 745183-5AMP 745185-6VESTAL IN1057AMP 87224-3AMP 87227-6SULLINS EZC18DTASAMP 745187-6TRW/UTC TC-SSO-33TCTONLY
TCTPart Number
120R57-{l09D120R57-{l15D20Z89-{)Q1120P34-{)Q1120P33-{l12120R76-{l36120R57-{l25D20H71-{)Q2087398
PARTS LIST SIA, DISPLAY MODULE 0807173
ReferenceSymbol
Miscellaneous
DISPu\YDISP CONN.
Description
LCD MODULEHEADER, DOUBLE ROW -16 PINCONTACT, SOCKETHOUSING, CONNECTOR - 4 POS.
Comp Mfr's Part Number
DENSITRON LM2457B4C40CTHAMP 102973-8AMP 350665-1AMP 1-640519-{l
TCTPart Number
120T64-{l01120P33-{l16020X95-{l01021 P71-{l04
PARTS LIST SIA, TRANSFORMER HARNESS 0807172
ReferenceSymbol
Miscellaneous
T1
13-10
Description
TRANSFORMERCONTACT, SOCKETCONNECTOR HOUSING
Comp Mfr's Part Number
EX-QUAL 111-1-{l17AAMP 350665-1AMP 1-640519-{l
TCTPart Number
120H50-{)Q1020X95-{l01021 P71-{l04
PARTS LIST SIA, INPUT/OUTPUT BOARD 0807386 (LMD40"N" version)
Reference TeTSymbol Description Compo Mfr's Part Number Part Number
Integrated Circuits
RNl ,2,5,9,14-18, RES. NETWORK, 10K COMMON CTS of BERNE 767-161Rl0K 121E50-11222,25,28RN3,10,11,21 RES. NETWORK, 68K COMMON CTS of BERNE 767-161R68K 121E50-132RN4,12, 13,19,20 RES. NETWORK 220K ISO. CTS of BERNE 767-161R220K 121E51-14424,26,27Ul-4 GATE ARRAY TCT7145 TCTONLY 121FOl-7145U6 QUAD LINE RECEIVER SIGNETICS MC1489AD 121 F54-GOlU7 OPERATIONAL AMPLIFIER MOTOROLA MC1741CD 121F52-GOlU8 QUAD LINE DRIVER SIGNETICS MC1488D 121F53-001U9-12 8 CH ANALOG MULTIPLEXER RCA CD74HC4051M 121F45-GOlU13-25 TRANSISTOR ARRAY SPRAGUE ULN2003L 121F50-GOlU26 QUAD 2-INPUT OR GATE NATIONAL MM74HC32M 121F14-001U27 HEX INVERTER NATIONAL MM74HC04M 121Fll-GOlU28 OCTAL D-TYPE FLIP-FLOP NATIONAL MM74HC374WM 121 F28-GOlU29 3 TO 8 LINE DECODER NATIONAL MM74HC138M 121F20-001
Capacitors
Cl-39,42,43,45, CAP. 0.1 uf, 50V, +80 -20% CER. M.E. GRM42-6Y5Vl04Z050BD 121C01-l0446-48, 53-76C40 CAP. 4.7uf, 20V, 10% TANT. MEPCO/CEN49MC475C020KOASFT121 C25-475C77,78 CAP..01 uf, 50V, 10%, CER. M.E. GRM42-6X7Rl03K50V 121C02-103
Diodes
CR2 DIODE 1N4005 AMPEREX BYD17J 121050-4005CR3 DIODE - ZENER 1N4752A THOMSON BZM 85 C 33 121025-4752
Resistors
Rl RES. 8.OOK, 1/4, 1% KOA SPEER RK73H2B-F8.OOK 121 E06-341R2 RES. 17.4K, 1/4W, 1% KOA SPEER RK73H2B-F17.4K 121 E06-342R3 RES. 34K, 1/4W, 1% KOA SPEER RK73H2B-F34.0K 121 E06-328R4 RES. 68.1 K, 1/4W, 1% KOA SPEER RK73H2B-F68.1 K 121 E06-343R5 RES. 10K, 1/4W, 1% KOA SPEER RK73H2B-Fl0.0K 121E06-112R6 RES. 3.01K, 1/4W, 1% KOA SPEER RK73H2B-F3.01 K 121 E06-277R7,8,15,16 RES. 68K, 1/4W, 5% KOA SPEER RM73B2BT683J 121E02-132Rl0-13 RES. 1K, 1/4W, 5% KOA SPEER RM73B2BT102J 121 E02-G88R14 RES. 10K, 1/4W, 5% KOA SPEER RM73B2BT103J 121E02-112
Miscellaneous
Jl CONNECTOR-EDGE POS. 36 AMP 1-530844-4 120R42-G36J2 CONNECTOR POS. 40 AMP 86418-2 020R29-G40J3 HEADER-RT ANGLE POS. 12 AMP 1-87233-2 120P35-G12J4 CONNECTOR-D-TYPE POS. 25 AMP 745187-8 120R57-G25
J5 CONNECTOR, EDGE, 90° SULLINS EZM22DTAS 120R77-044MSA CONNECTOR POS. 55 In CANNON KPT 45528-415 SPCL 120R70-G55MSB CONNECTOR POS. 55 In CANNON KPT 45528-428 SPCL 120R69-G55MSC CONNECTOR POS. 61 In CANNON KPT 45528-268 SPCL 120R71-G61
PRINTED CIRCUIT BOARD (only) TCTONLY 0807385
13-11
NOTES:
VISIONS... [ 11__ I ... I_I ~.....
I II(l(A$(O fOIl NODUC_ (_~?:IO l1/lJ ..... ""-073
:0 ."", IS 10 ..co:t:[ .... VAll _S 1 I f~ ""-"
rl
\,-J
~
13
O'
0
• •~ 3, ,
" 120294-018 HAAHE$S.l>OU8l.E-ENOE:D frw!W: '6 PIN iWi4-iiii• · " 011,t,22-0UC .ASHER-LOCK. INT, loom 16 14211(1
• • " 0101<01-01 NU -!iX• -" •16 O1OH23-01XlO W' • TH 0 CUTTING 6-32 x ,
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