TYPE NUMBER MC1531F WC1531G WC1S31L MC1533F MC1533F MC1533G MC1533G MC1533L WC1535F MC1535G MC1535L WC1536G MC1537L MC1539G MC1539L MC1556F MC15566 MC1556L MC1556N(8) MC15S6T MC1556V WC1558G WC1558L MC1558N(8) MC1558NG MC1S5S8NL MC1558NU MC1558SG MC1558SL MC15S8SU MC1558T MC1558U MC1558V MC1709AF MC1709AG MC1709AL MC1709CF MC1709CG MC1709CL MC1709CP MC1709CP1 MC1709CP2 WC1709CU MC1709F MC1709G MC1709L MC1709U MC1710CF MC1710CG MC1710CL MC1710CP MC1710F MC1710G MC1710L MC1711CF MC1711CG MC1711CL MC1711CP MC1711F MC1711G aan MTU MTU MTU MTU oBS| MTU OBS| MTU MTU MTU MTU MTU) MTU MTU MUG MTU MUG MUG MUG MTU MTU MuG| MTU MTU MTU MTU SJU MTU MUG MTU MTU MTU MTU MTU MTU} MTU MTU MTU MTU aA}Cc SLEW cM PS P |M | GBP | RATE [Vst | Ve | Ton | Avot | Vio Ig ho Prot | lour |Vout| Vicm] Vior | dVio/AaT | Po lo | RR RR | Rw p | P| MIN | MIN [MAX |MAX|MAX] MIN {MAX [MAX |MAX | MAX | MIN | MIN|MAX} MAX] MAX [MAX [MAX] MIN 7 MIN [MIN GPU| EXT 0.3V/uS} +9V! -9V)125C | 68dB | LOMV |1SONA | 25NA/SOOMWF) SMA j4.5V] 2V) SV] 30uV/C 1L50MW 65dB | 74dB | 1M GPU) EXT 0.3V/uS] +9] -9V/125C | 68dB | 1OMV J1SONA | 25NA|/680MWF] SMA] SMV) 2V| SV] 30UV/C [LSOMW 65dB | 74dB ; 1M GPU] EXT 0.3V/uS} +9V] -9V}125C | 68dB | 1OMV J1S5ONA | 25NA IWF) SMA'4.5V) 2V) SV) 30UV/C BSOMW 65dB | 74dB | 1M GPU) EXT @.2V/uS] +20V |-20V)125C | 92dB) SMV) luA|.15UA/5OOMW | 6MA) l2v! 20V) 10V |} 20uV/C IL70MW 90dB | 76d8 SOOK GPU] EXT 0.2V/uS| +20V |-20V]125C | 92dB) SMV) luA|.15UA/SOOMWF) 6MA] 12V{ 20V} 10V) 20uv/C 1170MW 90dB | 76dB 500K GPU} EXT 0.2V/uS) +20V/-20V)125C | 92dB} SMV! 1luA|.15uUA/680MWF) 6MA| 12V; 20V] 1OV} 20uV/C 170MW 90dB | 76dB 500K GPU] EXT 0.2V/uS} +20V|-20V!125C | 92dB | SMV | uA |.15UA|680MWF| 6MA| 12V | 20V| 10V| 20UV/C 1L70MW 90dB | 76dB BOOK GPU) EXT 0. 2V/uS} +20V}-20V)125C | 920B | SMV} luA}.15uA IWF] 6MA; 12V{ 20V| 10V} 20uV/C [1 70MW 90dB | 76dB 500K DGU! EXT 0.2V/uS} +10V}-10V}125C | 72dB} 3MV} 3UA {0.3uA/SOOMWF} .3MA} 3V! 10V/] SV} 15uV/C ISOMW 70dB | 70dB | 10K DGU} EXT 0. 2V/uS] +10V)-10V}125C | 72dB | 3MV | 3uA |0.3UA/680MW | .3MA] 3V] 10; SV] 2SuV/C LSOMW 70dB | 70dB | 10K DGUIEXT) [Q.2V/uS) +10V)-10)125C | 72dB) 3MV| 3uA/0.3UA/680MWF; .3MA/} 3V]) 10V) SV] 15uV/C (LSOMW] . 700B | 70dB | 10K HYO} INT| .3MHZ|0.5V/uS} +40V |-40V/125C j100dB} SMV| 20NA|) 3NA/680MWF] 1MA} 30V} 40V) 80V . 24MW | 4MA| 80dB| 80dB | 3M DGU;EXT) . [0.1/uS) +18V/-18V)125C | 88dB) SMV |0.5uA |0.2UA|7SOMWF] SMA] 12V} 18) 5V) lOUV/C 225MW) . 700B | 76dB [150K GPU} EXT 0. 4V/uS| +18V/-18V)125C | 94dB | 3MV ISOONA | 7SNA{680MWF}10MA| LOV| 18| 36V| lOUV/C |. SMA | 80dB | 76dB [150K GPU EXT 0. 4V/uS] +18V]-18V}125C | 94dB | 3MV [SOO0NA} 75NA|750MWF}1OMA | 10V; 18| 36V| 10UVv/C SMA | 800B | 76dB 10K SBA] INT| .SMHZ| 1V/uS) +22}-22V/125C |100dB | 4MV| 15NA| 2NA|680MWF) 6MA) 12V| 22V| 22V| 30uUV/C | 45MW} 2MA| 80dB| 80dB {1.5M SBA] INT} .SMHZ} 1V/uS|+22V}-22V)125C |100dB | 4MV| 15NA) 2NA/680MWF) 6MA) 12V! 22V) 22V} 30UV/C | 45MW| 2MA| 80dB! 80dB /1.5M SBA| INT} .SMHZ| 1V/uS}+22V|-22V}125C |L00dB | 4MV) 1SNA| 2NA|680MWF) 6MA| 12V) 22V) 22V| 30uV/C | 45MW| OMA! 80dB/ 80dB 11. 5M SBA] INT} .SMHZ| 1V/uS) +22V}-22V)125C |100dB | 4MVj 15NA} 2NA/68OMWF) 6MA/ 12V) 22V) 22V| 30uV/C | 45MW! 2MA} 80dB| 80dB /1.5M SBA] INT] .SMHZ} 1V/uS| +22V/-22V|125C }100dB | 4MV} 15NA| 2NA|SOOMWF] 6MA| 12V) 22| 22V| 30UV/C | 45MW| 2MA) 80dB| 80dB /1.5M SBA) INT) .SMHZ| 1V/uS} +22V|-22V/125C |100dB | 4MV| 15NA] 2NA|680MWF) 6MA] 12V; 22V) 22V) 30UV/C | 45MW]) 2MA! 80dB| 80dB [1.5M DGK} INT} .SMHZ 0. 3V/uS} +22V}-22/125C | 94dB | SMV |0.5uA |0.2UA/680MWF| SMA} 12V) 15) 30V] SQuV/C /1SOMW) 5MA| 70dB} 76qB |300K DGK] INT| . SMHZ|0.3V/uS) +22V/-22)125C | 94dB | SMV |O.5uA |0.2uA|750MWF| SMA) 12V| 15V] 30V] SQUV/C IL5OMW{ 5MA| 70dB| 76dB |300K DGK| INT| .SMHZ|0. 3V/uS| +22 |-22V]125C | 94dB | SMV |0.5uA |0.2uA|400MWF| SMA| 12V] 15V] 30V . ILSOMW | SMA | 70dB) 76dB 300K DLN) INT} .SMHZ|]0.3V/uS) +22V)-22V}125C | 94dB | SMV |O.5uA 10. 2uA;}680MWF} SMA} 12V] 15V| 30V| 50uV/C |LSOMW| SMA| 70dB| 76dB /300K OLN] INT] .SMHZ 40. 3V/uS| +22V]-22V}125C | 94dB} SMY |0.5uA |0.2UA|7SOMHF) SMA] 12V/ 15V| 30V| SOuV/C |LS5OMW| SMA] 70dB| 76dB |300K DUN] INT| .SMHZ |0.3V/uS| +22V|-22V/125C | 94dB| SMY [0.SuA |0.2UA|750MWF| SMA! 12V/ 15V| 30V; SOUY/C {LSOMW| SMA| 70dB| 76dB (300K DHS] INT) .SMHZ| 3V/uS) +22V}-22V|125C ; 94dB | SMV 0. 5uA |0.2uA|680MWF} 5MA| 12V] 15V| 30j} SOuV/C ILSOMW| SMA} 70dB| 76d8 |300K DHS] INT) .SMHZ} 3/uS) +22V}-22)125C | 94dB | SMV 0. SUA |0.2UA|75OMWF} 5MA| 12V/ 15V| 30V) 5QUV/C |LSOMW| SMA} 70dB| 76dB |300K DHS} INT] .SMHZ} 3V/uS| +22V|~-22V/125C | 94dB| SMV {0.5uA |0.2uA|75OMWF) SMA] 12V) 15V) 30V| 50uV/C |L50MW| 5MA| 70dB/ 76dB !300K DGK) INT} . SMHZ}0.3V/uS} +22V)-22V|125C | 94dB] SMV /0.5uA/0.2uA/5OOMWF} SMA| 12V! 15V} 30V . SOMW} SMA | 70dB; 76dB |300K DGK] INT] . SMHZ |0.3V/uS| +22V)-22V]125C | 94dB} SMV /0.5uA |0.2uA|7S5OMWF) SMA] 12V/ 15V| 30V; SOUV/C |LSOMW| SMA] 70dB) 76dB |300K DGK! INT| . SMHZ |0.3V/uS| +22V}-22V/125C | 94dB) SMV 10.5uA /0.2uA|400MWF) SMA| 12V\' 15V] 30V . ILSOMW! SMA} 70dB| 76qB /300K GPU) EXT| . 3MHZ|.15V/uS/ +18|-18V|125C | 88dB | 2MV |200NA| SONA!|SOOMWF| SMA| 12| 10| 5V/ 10uV/C [LO8MW| 4MA| 80dB| 80dB |350K GPU) EXT} .3MHZ| .15V/uS] +18]-18V}125C | 88dB | 2MV |200NA| SONA|}680MWF} SMA| 12/| 10| 5V|} LOuV/C ILO8MW| 4MA| 80dBj 80dB |350K GPU! EXT] . 3MHZ} .15V/uS| +18V)-18V}125C| 88dB} 2MV /200NA| SONA|75OMHF| SMA] 12V| 10} 5| LOUV/C /108MW} 4MA| 80dB! 80d8 /350K GPU) EXT| . 3MHZ} .15V/uS| +18V{-18V] 75C | 82dB |}7.5MVj1.5uA |0.5uA}SOOMWF| SMA| 12V) lov) SV . 2O0MW 65dB | 74dB} SOK GPU] EXT| .3MHZ| .15V/uS] +18V|-18V] 75C | 82dB 7. SMV |1.SuA ]0.5uA]680MWF| SMA|{ 12V| 10V] SY L200MW 65dB | 74dB | SOK GPU} EXT| .3MHZ| .15V/uS] +18V}-18V) 75C | 82dB |7.5MV |1.SuA ]0.5uA] 75OMWF} SMA| 12V] 10V) SV 0OMW 650B | 74dB; SOK GPU} EXT) . 3MHZ| .15V/uS| +18V|-18V] 75C} 82dB /7.SMV }1.5uUA|0.5UA/62S5MWF} SMA} 12V} 1OV| SV 00MW 65dB | 74dB| SOK GPU) EXT| . 3MHZ|.15V/uS! +18V}-18V) 75C| 82dB |7.SMV |1.5UA/0.5uA;625MWF) SMA) 12V| 10V) 5V OOMW 65dB} 74dB) SOK GPU) EXT) .3MHZ|.15V/uS| +18V)-18) 75C} 82dB |7.5MV |1.5uA |0.SuA/625MWF| SMA] 12V; 10) SV 200MN 65dB| 74dB) SOK GPU! EXT] . 3MHZj| .15V/uS| +18V|-18] 75C) 82dB j7. SMV |1.5uA /0.5uA]750MWF|} SMA| 12V) 10V] 5V . 200MW 65dB | 74dB/ SOK GPU] EXT) . 3MHZ| .15V/uS] +18V!-18V]125C| 88qB] SMV |SOONA |200NA|SOOMWF) SMA} 12V] 10V} 5V/ 15uV/C /L6SMW 7008 | 7608 /150K GPU] EXT] . 3MHZ| .15V/uS} +18V!-18V]125C| 88dB| SMV |SOONA |200NA|680MWF) SMA! 12V/ 10V; SV] 15uV/C /165MW 700B | 76dB }150K GPU| EXT) .3MHZ| .15V/uS) +18V|-18|125C | 88dB| SMV ISOONA |200NA|7SOMWF). 5MA/ 12; 1OV| 5SV{ 15uV/C |L65MW 700B | 76dB }150K GPU| EXT) .3MHZ| .15V/uS| +18|-18|125C} 88dB| 5MV /SOONA |200NA|7SOMWF| 5MA| 12/ 10V| 5V| 1SuV/C /L65MW| . 700B{ 76dB }150K CPR) EXT). . +14) -7) 75C; 60dB} SMV} 25UA] SuA;SOOMWF] SMA] 1V) 7V] SV} 20uV/C /LSOMW] 9MA| 70dB] . CPR! EXT +14V) -7) 75C} 60dB/} SMV} 25uA] SuA|/680MWF] SMA] lV) 7V! SV) 20uV/C /LSOMW] 9MA| 70dB CPR] EXT +14) -7) 75C| 60dB] SMV} 25uA] SuA|625MWF] SMA] 1V) 7V} SV) 20uUV/C /LSOMW) SMA | 70dB CPR] EXT +14V) -7) 75C| 600B] SMV} 25uUA! SUA; 625MWF] SMA] LV) 7) SV) 20uV/C /1S0MW) OMA! 70dB CPR] EXT +14V1 -7V/125C} 62dB) 2M; 20UA} 3UA;/SOOMWF! SMA; 1) 7} SV] 1OUV/C |L5OMW! SMA] 80dB CPR] EXT +14V) -7V/125C | 62dB) 2M} 20UA| 3uA/680MMF} SMA; 1| 7; SV! 1OUV/C |LS5OMW! 9MA| 80dB CPR] EXT +14V) -7V)125C| 62dB| 2MV| 20UA] 3UA/625MWF| SMA} 1; 7V| SV| 10UV/C |1SOMW! 9MA| 800B DCP] EXT +14| -7} 75C| 57dB] SMV)100UA} 25uA|SOOMWF] 5MA|2.5V; 7V| 5| 20uV/C 200MW . DCP] EXT +14V) -7) 75C| S7dB} SMV /100UA] 25uUA/680MWF; SMA |2.5V) 7V} SV) 20U/C 200MW OCP] EXT +14V| -7V} 75C| 57dB| SMV /100UA) 25uA/625MWF] SMA|2.5V; 7V| SV} 20UY/C 200MW DCP} EXT +14V) -7) 75C| S7dB; SMV /1O0UA] 25uUA/625MWF] SMA!2.5V;} 7V) SV) 20u/C 200MW DCP] EXT +14V) -7V}125C | 58dB}3.5MV} 7SUA) 1OUA|SOOMWF) SMA/2.5V) 7| SV! 20uY/C |200MW OCP) EXT +14V/ -7V}125C | 58dB|3.5MV| 7S5uA| 10QUA|680MW | SMA/2.5V) 7V| 5j 20uY/C |200MWFor detailed explanations of column heading notations, see App. A Also for ready references the More important abbreviations used in the column headings are listed below LEFT HAND PAGE APP = application (codes at APP.E.} CMRR = common mode rejection ratia CMP = compensation (frequency) dV,9/dT = input offset voltage temperature drift GBP = gain bandwidth product lh = input bias current Ie = input bias offset current 1. = quiescent supply current MFR = manufacturer (codes at Apo.C.} P, = quiescent power consumer PSRR = power supply rejection ratio View == common mode input voltage rating Vi = = differential input voltage rating V., == input offset voltage V; = de supply voltage RIGHT HAND PAGE Lead out coding summary (details at APP.G.} for different cases (APP F A = gain adjust 8 = bias adjust C = case E = inverting put E+ = non-inverting input F.F* = input frequency compensation G = ground J = high level input K == output, open collector L = output, open emitter M = metal case N = Not connected Q = special terminal R.R* = outputs 5 = strobe T1* = offset balance V+ = +ve de supply \- = ve de supply W = quard ring X = blank positon, no lead ++ = +ve supplementary de supply =ve supplementary dc supply 6.9* == output frequency compensation EUROPE USA ' CASE LD] LD] LO] LO]; LO] LO} LO] LO}LO) LO} 10] LD] Lo} td) LO} tO} SuUBsti suBsTI. |S! TYPE {APP FI 1 2/3; 4 5 8 7 8] 9] 10] 41) 12 113)14) 15] 16 TUTE TUTE S| NUMBER FLP-10/3CjE+ |E- |G |- JR [V+ iF JF* |o | of 0) MC1531F TOS-10/1MJE+ JE- |G |V- JR V+ [FO Fe jo | ot] oy) 2] ed. 01MC15316 DIL-14/1C/@ |[@* IN JE+ JN JE- |- |G JN | N |R | Vt iF [F* ~ ]O{MC1531L FLP-10/3G/E+ 18 |- |R [V+ |+ [V+ |F JF*] E- O}MC1533F FLP-10/3G/E+ j@ |V- |R |+ JA |T JF JF*] E- 0)MC1533F TOS-10/1M/E- JE+ |@ |V- [R |+ [V+ [V+ |F | FF 0)MC1533G TOS-10/1MjE- JE+ ]@ |V- JR iV+ JA TT JF YF) ot wt wd. 0)MC1533G DIL-14/1C|N JF |F* |E- JE+ |g |V- [IN JN | N | R | Vt [V4 V+ Q]MC1533L FLP-14/3C/R2 }g2 |F2 |F*2|E+2}E-2)- /E-1/E+ Fl} F*l) 61 (RI | V+ O}MC1535F TOS-10/1M/- |E-2;E+2| 62 |[R2 |V+ |R1 |@l JE+] E-] 0)MC1535G DIL-14/1C|R2 |@2 |F2 | F*2/E+2/E-2/- |E-1/E+] Fl | F*1) @1 /R1 | + UA7490M = 40) MC1535L TOS-8/1M |T |E- JE+ {V+ |T* JR | V+ IN foe fo ef oe} ade LM143 0} MC1536G DIL-14/1C|@2 }R2 |F2 |F*2;E-2)E+2|V- |E+1}E- Fl | F*) Ri [ol | V+ : RM15370C = }0}MC1537L TOS-8/1M |F JE- JE+ |V- Jo JR [V+ HPF Yo} 2} ep ep ed TAAS22 UA7O9HM 0}MC15396 DIL-14/1CjN JN IF JE~ JE+ |- IN JN J@ | R | V+ F* IN IN LM709J UA709DM = |O|MC1539L DIL-14/1C)N JN |T |E- [E+ |- JN IN JT*TR | Vt |N IN IN : MC1556L j0|MC1556F TOS-8/1M |T |E- JE+ |V- |T* JR [V+ JN efoef oe fo. pede LM143H MC1SS6T = 0 | MC15566 DIL-14/1C|N |N |T JE- JE+ |- |N GN [TF] R | +|N JN IN LM143D MC1556F O}MC1S56L DIL-8/1P |T JE- JE+ |V- |T* JR | V+ IN : S5556 O}MC15S6N(8) TOS-8/1M {T |E- |E+ |/V- |T* JR [V+ IN SS556T MC1556G) = [0 }MC1556T DIL-8/1P {7 JE- JE+ fV- |T* JR [V+ IN : SSSS56 OIMC1S56 TOS-8/1M |R1 JE-1/E+1}V- jE+2)E-2]R2 |V+ p 2] 2] 2 fy . | ed. TBC1458 =| LM1558H =O | MC1558G DIL-14/1CjN JR1 JN |N JE-1/E+1]V- JE#2}E-g N |N | R2 |N | V+ . O}MC1558L DIL-8/1P [RL JE-1/E+1{V- |E+2)E-2|R2 | V+ LM1558J = |MC1558U = JO /MC1558N(8) TOS-8/1M {Rl |E-1/E+1/V- |E+2}E-2)R2 | V+ : : 0) MC1558NG DIL-14/1C|N JR1 JN JN |E-1IE+1)v- |E#2/E-4N |N |R2 |N [V+ Q)MC1558NL DIL~8/1C |R1 |E-1)E+1/V- |E+2)E-2)R2 | V+ O}MC1S5S8NU TOS-8/1M |R1 |E-1/E+l)V- [E+2]/E-2)R2 V+ | 2} 2] ete Pe]. 0)MC1558SG DIL-14/1C/N |R1 JN JN [E-LJE+1/- |E+2j/E-aN |N |R2 IN | V+ O)MC1558SL DIL-8/1C RL JE-L/E+1}- |E+2/E-2)R2 |V+ Q)MC1558SU TOS-8/1M [RI JE-1JE+1/V- |E+2)-2)R2 | V+ TBC1458 = {MC1558G)= JO} MC1558T DIL-8/1C |R1 |E-1}E+l1)V- | E+2)E-2)R2 [V+ . LM1558J O}MC1558U DIL-8/1P JRL |E-1JE+1/V- |E+2}-2/R2 |V+ | .f. LM1558J WC1558U O}MC15S8V FLP-10/3CjN |F JE- |E+ |V- jg JR [V+ FEIN SNS2709AFA]UA709AFM = |0}MC1709AF TO5-8/1M |F JE- }E+ |- |@ |R |V+ iF* : UA7O9AHM = |0)MC1709AG DIL-14/1C]N |N JF JE- JE+ |- JN JN | |R | V+ |F* IN JN LM709A) |UA709ADM = |01WC1709AL FLP-10/3C iN |F JE- |E+ |- |@ |R {V+ [FEIN SNS2709AFA]UA709FM = |0}MC1709CF TOS-8/1M |F jE- JE+ |V- [@ JR |V+ (FY 1.) 2} 2p ep]. TAAS21 UA7O9HC = |0 }MC.1709CG DIL-14/1C|N JN JF JE- ;E+ |V- JN IN j@ |R | V+ |F* IN IN TAAS21A = |UA709DC = 0] MC1709CL DIL-14/1PIN |N JF JE- JE+ |- JN JN [6 |R | V+ /F* IN JN TAAS21A = |UA7090C = {0} MC1709CP DIL-8/1C |F |E- |E+ |V- |@ JR |+ [FE] .] 2} ep. ed. LM709CN8 |}UA709TC = |0]MC1709CP1 DIL-14/1PIN JN JF }E- |E+ |V- JN [N [@ |R | V+ |F* IN YN TAAS21A = | UA7090C = |0 | C1 709CP2 DIL-8/1C }F /E- JE+ [- |g |R |V+ |F*] .] . LM709CN8 |UA709TC = |0|MC1709CU FLP-10/3C}N |F JE- JE+ |V- |@ JR [V+ [FY IN : UA709FM 0]MC1709F TOS-8/1M |F |E- [E+ |- |g JR |+ jF* TAAS22 UA709HM 0]MC1709G DIL-14/1CIN |N fF JE- }E+ }- JN IN J@ | R | + |F* IN IN LM709J UA7090M 0}MC1709L DIL-8/1C JF JE- E+ |V- |e [R |+ JF yo]. : SNS2709AJP |0}MC1709U FLP-10/3C/G |E+ JE- JN |- JR JN [V+ IN TN SFC2710PM |UA710FM = |0|MC1710CF TOS-8/1M |G |E+ JE- JV- [IN JN JR [Vt] ot 2] . |. Ped. SFC2710C |UA710HC |0}MC1710CG DIL-14/1C|N |G JE+ JE- JN |- JN JN YR JN [V+ IN IN) IN SFC2710C |UA7100C O}MC1710CL DIL-14/1PjN |G |E+ JE- |N |- JN JN TR [N | + IN IN IN SFC2710EC | UA7100C O}MC1710CP FLP-10/3C |G |E+ |E~ jN |- |R JN J+ IN | N SFC2710PM |UA710FM = |0}MC1710F TOS-8/1M |G |E+ |E- [V- IN JN JR [Vt] oP 2 ft . fe Ped. SFC2710M | UA710HM 0}MC1710G DIL-14/1C)N |G JE+ JE- JN |- JN IN TR [N | + JN IN IN SFC2710KM | UA710DM O]MC1710L FLP-10/1C{E-1jE+i|V- JE+2|E-2)S2 jR |V+ |G | Sl SFC2711PM |UA711FM = |0]MC1711CF TOS-1LO/IMjG Sl JE-LJE+1I- [E+2]E-2]S2 JR f+] . |. fo]. SFC2711C | UA711HC 0|MC1711CG DIL-1L4/1C iN JE-1JE+1]/V- JE+2]E-2|N IN {S2]R | + |G {Sl ]N SFC2711EC |UA711DC O}MC1711CL DIL-14/1P|N JE-1JE+1}- jE+2;E-2(N IN |S27R | V+ {[G {Sl ]N SFC2711EC |UA711DC OyMC1711CP FLP-1O/ICJE-LJE+1/V- JE+2)E-2/S2 |R |+ |G {S12 : UA711FM OyMC1711F TOS-10/1M|G |S1 |E-1{E+1|V- | E+2]E-2/S2 |R | V+ SFC2711M {UA711HM = |0|MC1711GAppendix A The general layout plan of the information in the tables of this compendium should be immediately evident from the data tabulation explanatory chart set out overleaf. Supporting Appendices with additional information are: App.B Glossary of Opamp Terms App.C Tabulation Codes for Manufacturers App.D IC Manufacturers House Numbers App.E Tabulation Codes for Applications App.F Case Outline and Leadout Diagrams App.G = Codes for Leadout Connections Unit symbols used in the tables are: A = amperes C = centigrade dB = decibels G = gigaohms (megohms x 10?) GHZ = gigahertz (megahertz x 10) K = kilohms KHZ = kilohertz M = megohms MA =milliamperes,mA MAX = maximum MHZ = megahertz MIN = minimum MV =nmillivolts MWC = milliwatts, case at 25C MWEF = milliwatts, free air at 25C MWH = milliwatts, heat sink, 25C NA = = nanoamps(microamps x 1073) NV = nanovolts (microvoits x 107%) PA = = picoamps (microamps x 107!?) R = ohms T = teraohms (megohms x 10) Vv = volts WC = watts, case at25C WF = watts, free airat25C WH = watts, heatsink, 25C pA = microamps us = microseconds LV = microvolts uw = microwatts uWF = microwatts, free air at 25C Where a unit symbol appears in the middle of a value, it indicates the position of the decimal point, e.g. 3K3 =3-3K. Explanatory notes to tabulationsAppendix A M) AEC SLEW cM PS TYPE Fi; P}M| GBP | RATE | Vs' | Vs" | Top | Avot | Vio Ie ho Prot | lout | Vout] Vicm| Ving | dViodT | Pa lo RR RR | Rw NUMBER P P MIN MIN MAX |MAX|MAX] MIN | MAX 1] MAX [MAX | MAX MIN | MIN| MAX! MAX MAX MAX |MAX] MIN | MIN [MIN (EXAMPLE) LHOO22CH NAUFET|INT) .3MHZ] 1/uS/+22V]-22V) 85C| 97dB! 6MV| 25pA) SpA] SOOMWF] LOMA] 1OV! 15/ 30V| 15uV/C| 85MW! 3MA] 70dB] 700B)/0.17 TYPE No. * NUMERO- Ry MIN ALPHABETIC =MIN IN- LISTING PUT RESISTANCE MFR= MANUFACTURER PSRR MIN= CODED AS APP. C MIN. POWER SUPPLY REJECTION RATIO IN DB APP = APPLICATION CODED AS APP. E CMP = FREQUENCY COMPENSATION WITH INT =INTERNAL EXT = EXTERNAL CMRR MiN=MIN. COMMON MODE RE- JECTION RATIO IN DB lg MAX=MAX. QUIESCENT (NO SIGNAL, NO LOAD) GBP MIN=UNITY GAIN CURRENT CONSUMPTION IN MA BANDWIDTH PRODUCT, MIN; IN KHZ, MHZ, or GHZ PagMAX = MAX. QUIESCENT a (NO SIGNAL, NO LOAD} SLEW RATE, MIN. IN VOLTS POWER CONSUMPTION IN MW PER MICROSECOND. V/uS dV,9/dT MAX = MAX. INPUT Vs' MAX = MAX. PERMISSIBLE OFFSET VOLTAGE TEMPERATURE +VE OC SUPPLY VOLTAGE IN VOLTS, V DRIFT IN pV/C OR MV/C Vs. MAX=MAX PERMISSIBLE Viop MAX = MAX. PERMISSIBLE -VE DC SUPPLY VOLTAGE IN VOLTS, V DIFFERENTIAL INPUT VOLTAGE IN V. Vicm MAX = MAX. PERMISSIBLE COMMON-MODE INPUT VOLTAGE Top MAX = MAX. PERMISSIBLE OPERATIONAL c IN VOLTS, V AMBIENT TEMPERATURE IN Ayo. MIN = MIN. OPEN-LOOP VOLTAGE GAIN IN DB Vour MIN = GUARANTEED MIN, OUTPUT VOLTAGE, PEAK VALUE, IN VOLTS, V Vig MAX = MAX INPUT OFFSET VOLTAGE AT 25C IN MV or HV. lour MIN =GUARANTEED MINIMUM OUTPUT CURRENT, PEAK VALUE, IN MA OR pA. I, MAX = MAX. INPUT BIAS CURRENT AT 25C IN MA, vA. nA or pA Fre MAX = MAX. PERMISSIBLE ieee DISSIPATION IN W, mW, wW WITH F =FREE AIR 25 C=CASE 25C. H=HEATSINK 25C. lig MAX=MAX. INPUT OFFSET CURRENT AT 25C IN MA, pA, nA, OR pA INOTE: FOR FURTHER EXPLANATION * Rw EXPRESSED AS OHMS {R), KILOHMS (kK), OF SPECIAL TERMS SEE APP. B] MEGOHMS (M}, GIGAOQHMS (G) OR TERAOHMS {T}LEFT HAND PAGE For detailed explanations of column heading notations, see App. A. Also for ready references the more important abbreviations used in the column headings are listed below: APP = application (codes at APP.E.) CMRR = common mode rejection ratio CMP = compensation {frequency} dV,/dT = input offset voltage temperature drift = gain bandwidth product input bias current input bias offset current ly = quiescent supply current = manufacturer {codes at App.C.) Py, = quiescent power consumer PSRR = power supply rejection ratio = common mode input voltage rating = differential input voltage rating Vig = input offset voltage V, == de supply voltage GBP ae oil MFR View Ving RIGHT HAND PAGE Lead out coding summary (details at APP.G.) for different cases {APP.F.} A = gain adjust B = bias adjust C = case E = inverting input m + ! = Non-inverting input = input frequency compensation = ground = high level input = output, open collector Output, Open emitter = Metal case = Not connected special terminal R* = outputs = strobe ' = offset balance +ve de supply ve de supply guard ring = blank position, no lead +ve supplementary de supply ve supplementary de supply == output frequency compensation om = * I mowzezrrtn | <= < ll 4+ XSF + hou we dl Appendix A CASE LD} LO] LO} LO] LO] LO] LD] LD] LO] LO (APP F) 1 2)3 4 $1 6 7 8] 9410 LD 11 LD 12 LO 13 Lo 14 LO 1S LO 16 EUROPE USA ' SUBSTI- SUBSTI- S| TYPE TUTE TUTE S|} NUMBER TOS-8/1M |T |E- [E+ jV- |T* [Ro [V+ [N CASE = PACKAGE OF DIFFERENT TYPES CODED ACCORDING TO APP. F FIRST NUMBER INDICATES NUMBER OF LEAO POSITIONS EG DIL-14=14-LEAD DUAL-IN-LINE PACKAGE L101, LD2, ETC=LEAD NUMBERS WITH CONNECTIONS ACCORDING TO PAGE FOOTNOTE OR APP. G. LHOO22H = {0} LHOO22CH TYPE No. REPEATED ON R.H. MARGIN ISS =!SSUE NUMBER OF DATA ENTRY USA SUBSTITUTE = SUGGESTED ALTERNATIVE AVAILABLE IN USA. EURO SUBSTITUTE = PROELECTRON STANDARD OR OTHER TYPE AVAILABLE IN EUROPEADU ANG ANU BLG BLU BUG BUU CMG DAG DAU FAG FAU FEG FUJ HAG HAU HIJ ING INU ITG Advanced Micro Devices Inc., 901 Thompson PL, Sunnyvale, CA 94086, USA Analog Devices Ltd, Central Ave., East Molesey, KT8 SBR, Surrey, UK Analog Devices Inc., P.O. Box 280, Norwood, Mass., 02062 Bell & Howell Ltd, Lennox Road, Basingstoke, Hants, UK Bell & Howell (Control Products Divison), 706 Bostwick Ave, Bridgeport, Conn. 06605, USA Burr-Brown International Ltd, 17 Exchange Rd, Watford, WQD1 7EB, Herts., UK Burr-Brown Research Corp., P.O. Box 11400, Tucson, AZ. 85734, USA Computing Techniques Ltd, Brookers Rd, Billingshurst, Sussex, RH14 9RZ, UK Datel UK Ltd, Stephenson Close, Andover, Hants, UK Datel Systems Inc., 1020 Turnpike St., Canton, MA02021, USA Fairchild Camera & Instrument (UK) Ltd, 230 High St., Potters Bar, Herts., UK Fairchild Semiconductor 464 Ellis St., Mountain View, CA 94042, USA Ferranti Ltd, (Electronic Department), Gem Mill, Chadderton, Oldham, OLS BNP, UK Fujitsu Ltd, 1015 Kamikodanaka, Kawasaki, Japan Harris Semiconductor (Memec) Ltd, Portway _ Ind. The Firs, Whitchurch, Nr. Aylesbury, Bucks., HP22 4JU, UK Harris Semiconductor P.O. Box 883, Melbourne, FL,32901, USA Hitachi Ltd (Semiconductor and IC Div.), 1450 Josuihonimachi, Japan Intersit Inc., 8 Tessa Rd, Richfield Trading Estate, Reading, Berks., UK Intersil Inc., 10900 N. Tantau Ave, Cupertino, CA, 95014, USA ITT Semiconductors Maidstone Rd, Foots Cray, Sidcup, Kent, Estate, Lancs., Kodaira City, Tokyo, Appendix C Tabulation Codes for Manufacturers ITU MNG MNJ MTG MTU MUG NAG NAU NIJ OAU oBS OTU PLG PRG PRU RAG RAU RCG RCU SAJ DA14 5HT, UK ITT Semiconductors 74 Commerce Way, Woburn, MA, 01801, USA Mitsubishi Shoji Kaisha Ltd, Bow Bells House, Bread St., London, EC4, UK Mitsubishi Electric Corp., 212 Marunouchi, Chiyoda-ku, Tokyo, Japan Motorola Ltd (Semiconductor Products Div.), York House, Empire Way, Wembley, Middlesex, HAS OPR, UK Motorola Semiconductor Products Inc., 5005 E. McDowell Road, Phoenix, AZ, 85008, USA Mullard Ltd, Mullard House, WC1E7HD, UK National Semiconductor (UK) Ltd, Harpur Centre, Bedford, MK40 3LF, UK National Semiconductor Corp., 2900 Semiconductor Drive, Santa Clara, CA, 95051,USA Nippon Electric Co. Ltd, 1753 Shimonumabe, Nakahara-ku, Kawasaki, Japan Opamp Labs Inc., 1033 N. Sycamore Ave., Los Angeles, CA 90038, USA Obsolete no longer commercially available. Optical Electronics Inc., P.O. Box 11140, Tucson, AZ, 85734, USA Plessey Semiconductors, Cheney Manor, Swindon, Wilts., SN2 20W, UK Precision Monolithics (Bourns Trimpot Ltd) 17/27 High St., Hounslow, Middlesex, UK Precision Monolithics (Bourns) Inc., 1500 Space Park Drive, Santa Clara, CA, 95050, USA Raytheon Semiconductor The Pinnacles, Harlow, Essex, CM19 5BB, UK Raytheon Semiconductor, 350 Ellis Street, Mountain View, CA, 94042, USA RCA (Great Britain) Ltd, Lincoln Way, Windmill Thames, Middlesex, UK RCA Solid State Division Route 202, Somerville, NJ,08876, USA Sanken Electric Co. Ltd, 1-22-8 Nishi-Ikebukuro, Toshima-Ku, Tokyo, Japan Torrington Place, London, Road, Sunbury-on-SGG SGI SHG SHJ SIG SIW SJG SJU SKU SLG SLU SOJ SPG Appendix C SGS-ATES (UK} Ltd, Planar House, Walton Street, Aylesbury, Bucks., UK SGS-ATES Componenti Spa, Via Olivetti, 2 Agrate Brianza, 20041, Milan, italy Shindengen Hyokuto Boeki Haisha Ltd, St. Alphage House, Fore St., London, EC2Y 5DA, UK Shindengen Electric Mfg Co.. Ltd, New Ohtemachi Bldng, 2-1, 2-chome, Ohtemachi, Chiyoda-ku, Tokyo, Japan Siemens Ltd, Great West Road, Brentford, Middlesex, TW8 9DG, UK Siemens Aktiengeselischaft, Richard-Strauss-Strasse 76, D-8000 Munchen 2, Postfach 202 109, W. Germany Signetics International Corporation Yeoman House, 63 Croydon Rd, London, SE20, UK Signetics Corp., 811 East Arques Ave, Sunnydale, CA. 94086, USA Silicon General Inc., 7382 Bolsa Avenue, Westminster, CA, 92683, USA Siliconix Ltd, 30A High St., Thatcham, Newbury, Berks., RG13 4JG, UK Siliconix incorporated, 2201 Laurelwood Road, Santa Clara, CA, 95054, USA Sony Semiconductor Corp., 141, Asa hi-sho 4, Atsuigi-shi, Kanagawa-ken, 243, Japan Sprague Electric (UK) Ltd, 159 High St., Yiewsley, W. Drayton, Middlesex, UB7 7RY, UK SPU TDG TDU TEB TEU TGG TGU THF THG TKJ TOG TOJ TRU ZEU Sprague Electric Company (Semiconductor Div.), 115 Northeast Cutoff, Worcester, MA, 01606, USA Teledyne Semiconductor, Heathrow House, Bath Road, Cranford, Houns- low, Middlesex, TW5 9QP, UK Teledyne (Ameico) Semiconductor, 1300 Terra Bella Ave, Mountain View, CA, 94032,USA Teledyne-Philbrick, Heathrow House, Bath Road, Cranford, Houns- low, Middlesex, TW5 9QP, UK Teledyne-Philbrick, Allied Drive at Route 128, Dedham, MA, 02026, USA Texas Instruments Ltd, Manton Lane, Bedford, UK Texas Instruments Inc. (Components Group), P.O. Box 5012, Dallas, Texas, 75222, USA Thomson-CSF (Sescosem), 50 Rue Jean Pierre Timbaud, BP 120, 92403, Courbevoie, France Thomson-CSF (UK) Ltd, Ringway House, Bell Rd, Daneshill, Basing- stoke, Hants., RG24 OGG, UK. Tokyo Sanyo Electric Co. Ltd (Semiconductor Div.), Oizumachi, Oragun, Gumma, Japan Toshiba (UK) Ltd, Toshiba House, Great South West Rd, Feltham, Middlesex, UK Toshiba (Tokyo Shibaura) Electric Co., 2~1, 5-chome, Ginza Chuo-ku, Tokyo, Japan Transitron Electronic Corp., 168 Albion St., Wakefield, MA,01881, USA Zeltex Inc., 940 Detroit Ave, Concord, CA, 94518, USA(General Note: Manufacturers often adopt their own in-house serial numbering for their ICs. Listed below are the initial letters of numerical series used by different manufacturers.) AD ADO AM AMD AMLM AMSSS AMU Cc CA CIA CMP CN DA EP ESL FSL FSS HA HEPC ICH ICL JM JSF L LA LF LH LM M MC MCC MCCF MCE MCH MIC MLF MLM MLMC MONO-OP N NC NE NH Analog Devices Analog Devices Advanced Micro Devices; Datel Advanced Micro Devices Advanced Micro Devices Advanced Micro Devices Advanced Micro Devices Bell & Howell RCA Teledyne-Philbrick Precision Monolithics Ferranti Teledyne-Philbrick Teledyne-Phitbrick Teledyne-Philbrick Teledyne-Philbrick Ferranti Harris Motorota Intersil Intersil Fairchild Thomson-CSF Analog Devices; SGS-ATES Teledyne-Philbrick National Semiconductor National Semiconductor National Semiconductor Mitsubishi Motorola Semiconductors Motorola Semiconductors Motorola Semiconductors Motorola Semiconductors Motorola Semiconductors ITT Semiconductors Motorola; Teledyne-Philbrick Motorola Semiconductors Motorola Semiconductors Precision Monolithics Signetics; Mullard General Instruments (obs.) Signetics; Mullard National Semiconductor Appendix D IC Manufacturers House Numbers OP Precision Monolithics P Teledyne-Philbrick PF Teledyne-Philbrick PG General Instruments (obs.) PP Teledyne-Philbrick RA Radiation (now Harris) RC Raytheon RL Raytheon RM Raytheon RSN Raytheon RV Raytheon Ss Signetics SA Teledyne-Philbrick SE Signetics; Mullard SFC Thomson-CSF SG Silicon General SH Fairchild SK RCA SL Plessey: Teledyne-Philbrick SN Texas Instruments SP Teledyne-Philbrick sa Teledyne-Philbrick Sss Precision Monolithics SU Signetics; Mullard T Teledyne-Philbrick Transitron TA AEG-Telefunken TAA Proelectron Standard TBA Proelectron Standard TBB Proelectron Standard TBC Proeiectron Standard TBE Proelectron Standard TCA Proelectron Standard TDA Proelectron Standard TDOB Proelectron Standard TOC Proelectron Standard TDE Proelectron Standard TL AEG-Telefunken TOA Transitron TSsc Transitron U Fairchild ULN Sprague ULS Sprague USL Tetedyne-Philbrick ZA Zeltex ZEL Zeltex ZLD Ferranti ZN Ferranti HA FairchildBDO CDA CHP CPR DBD DCP DFE DGK DGU DHS DLN DPI DPR DSB FET GPK GPU HCO HIR HPO HSR HVO LBC LCD LNA LOC LOV LOP LVD MWB OTA Balanced differentia!-output amplifier Current-difference amplifier Chopper-stabilized amplifier DC comparator Dual balanced differential-output amplifier Dual Comparator Dual fet-input opamp Dual general purpose opamp Dual general-purpose uncompensated opamp Dual high-slew-rate opamp Dual low-noise opamp Dual precision instrumentation amplifier Dual programmable opamp Dual super-beta opamp Fet-input opamp General-purpose, internally-compensated, opamp General-purpose, uncompensated, opamp High current output opamp High input resistance opamp High power output opamp High slew rate opamp High voltage output opamp Low input bias current opamp Low input offset current drift opamp Low noise opamp Low input offset current opamp Low input offset voltage opamp Low quiescent power opamp Low input offset voltage drift opamp Medium-wideband opamp Operational transconductance amplifier Appendix E Tabulation Codes for Applications PAA PIA PRA acD acPp QFE QGkK QaGu QLta QPI QPR QSB SBA TCP TFE TGK TGU TLN TLP TOT TPI TPR TSB VFA WBA XHG XLP XSR XWB Parametric amplifier Precision instrumentation amplifier Programmable opamp Quad current-difference amplifier Quad comparator Quad fet-input opamp Quad general-purpose, internally-compensated, opamp Quad general-purpose, uncompensated, opamp Quad low-quiescent-power opamp Quad precision instrumentation amplifier Quad programmable opamp Quad super-beta opamp Super-beta opamp Triple comparator Triple fet-input opamp Triple general-purpose, internally compensated, opamp Triple general-purpose, uncompensated, opamp Triple low-noise opamp Triple low-quiescent-power opamp Triple operational transconductance amplifier Triple precision instrumentation amplifier Triple programmable opamp Triple super-beta opamp Voltage-follower amplifier Wide-band opamp Extra-high-gain opamp Extra-low quiescent power opamp Extra-high slew rate opamp Extra-wide-band opampI A A* B Cc E+ m | T-xrxAGeCHOMTN ETACCOY * AnNDaUoOZz Connection Codes in Serial Order = Gain adjust, 1 = Gain adjust, 2 = Bias adjust or set = Case, package, screen Input, non-inverting, low-level Input, inverting, low-level Input frequency compensation, 1 Input frequency compensation, 2 = Ground, common, earth, zero volts Input, non-inverting, high-level tnput, inverting, high-level = Output, open collector = Output, open emitter = Metal casing = Not connected, i.e. isolated lead = Special terminal (consult manufacturer's data) = Output, 1 = Output, 2 = Strobe = Offset balance, trim or null, 1 = Offset balance, trim ornull, 2 = +vedc supply = vede supply = Guard ring = Blank position, lead omitted = +ve supplementary dc supply = ve supplementary dc supply = Output frequency compensation, 1 = Output frequency compensation, 2 Wot weal il Appendix G Codes for Leadout Connections Ht: Lead Assignments in Alphabetical Order Balance, offset, 1 =T Balance, offset, 2=T* Bias adjust=B Blank position, without lead = X Case=C Compensation, input, 1 =F Compensation, input, 2 = F* Compensation, output, 1=@ Compensation, output, 2 =9* DC supply, +ve=V+ DC supply, ve=V Frequency compensation, input, 1=F Frequency compensation, input, 2 =F* Frequency compensation, output, 1=@ Frequency compensation, output, 2=@* Gain adjust, 1=A Gain adjust, 2=A* Ground=G Guard ring=W Input, inverting, high-level =J Input, non-inverting, high-level =J + Input, inverting, low-level =E Input, non-inverting, low-level =E + Input offset voltage, adjust, 1=T Input offset voltage, adjust, 2=T* Lead omitted, blank position =X Lead in position but not connected=N Metal case=M Not connected, but lead in position=N Null, offset, 1=T Null, offset, 2=T* Offset voltage adjust, 1=T Offset voltage adjust, 2=T* Output, 1=R Output, 2 =R* Output, open-collector = K Output, open-emitter=L Package=C Special purpose terminal (data sheet to be consulted) =A Strobe=S Supply, dc, +ve=V+ Supply, dc, -ve=V Supply, dc, supplementary, + ve=+ + Supply, dc, supplementary, ve = Trim (offset voltage), 1=T Trim (offset voltage), 2=T*Appendix F HIL-12/1 HIL-14/1 25mm | MDL-8/2 (i=. 7 Me kh is . arm VT same Tae Somme , vam gf mm ca ' = 8 5mm 75mm 125mm ole MDL-10/3 MDL-14/4 SIH-10/1 . 87mm 4mm i ao t + amm je 76mm 9 10 x ! 83101213 14 re 6mm ame ine 875mm * SO aie | ro , 125mm a Me 125mm. le area SIL-7/A1 TO3-5/2 TO3-10/2 be 17 Sram - a | _ cerees aac} 3mm a = 25mm 123456? LS tomm max. | TO5-6/1 TO5-8/2 * 6 le 6/12 mm t ot = 85mm 85mm }-_ 85mm Cc - , a po TO5-8/3 12.3 TO5-8/4 TO5-10/2 gon, * Vi > 3mm mm 7 4 . , 6 5 7 6 2 6/12mm- & 85 ' BSmm 85mm t | TO5-12/1 nBa TO5-12/2 weal TO8-12/1 \2 aie 10 3 3 se 9 4 t 4 7 S765 15mm 6 612mm * 6/2mm # | | (2mm lead spacings} (2 5mm lead spacings) *12mmmin * TI84/2 T66-10/1 1 2, a 4 ao = 5 + po 6 48mm 10 max. t se 2mm. | 98 t 12 mm ve12 mmimin. t2en max mn (2mm lead spacings) {2mm lead spacings)Appendix F BML BEAMLEAD CHIP CFL FLIP CHIP CHP CHIP (face up} DIL-6/1 4 Thickness 0 2mm typ. Thickness 0: 2mm typ. Thickness O 2mm typ. = Edges 0-8-2 Smm typ. Edges 0-8-2:Smm typ. Edges 0-8 -2:5mmtyp. r UNDER + SIDE Bean leads Solder bumps Bonding pads (for details see manufacturer's data sheet) (for details see manufacturer's data sheet) {for details see manufacturer's data sheet) 75mm 25 mm 1413120 8 3 1 DIL-8/1 DL-10/1 DIL-12/1 DIL-141 BSAaoAAS + TOP 6mm e 7F 1234567 : ( Smom max. 75mm 7.5mm 75mm 75mm a 25mm 16 15141312 1 10 9 DIL-16/1 | DIM-5/4 DIM-7/5 DIM-8/3 TOP 6mm e 1234567 r | 12-5emn 4 By 16mm 44 _ * *y CSAP i m0 . - + t - RTO 6mm mm : 12mm min. I * - " er | 1234567. DIM-9/5 DIM-11/5 1234 DIM-14/1 coeecee FLP-5/6 eeee f. | As UNDERSIDE ni0'98765 jnm opee see coerce te 141312111098 be16 mma 25mm 25mmse om 5mm " r : TT TINTNT fe 1Omm oo * i 6mm ment f- 254mm 5mm _* IF 5mm FLP-6/1 FLP-6/2 FLP-8/2 daar f FLP-10/1 3.5mm 65mm &5mm 25mm * + min. 1 1 - om le Fe ~ 2:5mm max 1 , 10 [108 sr TOP G 4mm j3 Sg 3s 0 Gan _ + 45 67 = 2mm | (1-25 mm lead spacings) 2:5 mm max 5678 (rid FLP-10/3 < smm FLP-14/3 6.5mm FLP-16/4 oy 1 40 2 9 43 TOP 8 ; 24 (1. 25mm lead spacings) (1.25 mmlead spacings) Gass] 25mm 2 Sram 25mm 25mm max, max. Wax. max.