BLOCK DIAGRAM IS SHOWN BELOW OUTPUT, OUTPUT a 5 4 , x x I l BUFFERED BUFFERED | DELAY DELAY | | l 3 INPUT , INPUT GROUND MECHANICAL DETAIL IS SHOWN BELOW ro Pin Mo, a 7 5 /VO0y Op | | $S2FLDL- @TTL-___ IN, IN, | Pin Nao. 4 3 4O4 &r? O90 g252 MADE id SLO LISA ee [Ut + sso-.010 060 FYP. oon pia, Tye + be os , 100 TYP, 2b Pt O_O \ *Thru-hole Lead = B25 KE ne tt | * 1oTye Ce fae as OAT TYP, ae |= *Gull Wing Lead ij a 25 a O20 TYR. - jo TYR y | aE t | [ Paet | if [J ~ TYR OSOTYR | | O30 TYP. a |a *Tucked Lead TEST CONDITIONS 1. All measurements are Made at 25C. 2. Voc supply voltage is maintained at 5.0V DC. 3. All units are tasted using a Schottky toggle-type positive input pulse and one Schottky load at the output. a4. Input pulse width used is 100% longer than delay of module under test; spacing between pulses (falling edge to rising edge) is three times the pulse width used. OPERATING SPECIFICATIONS *Veo supply voltage: . . 6... ee ee 4.75 to 5.25V DG Vee supply current: Constant "On ww ee al Constante cl wi, ace ee kk ; Lagic 1 Input: . VOUIEHG: Scena aM ece jek dowels eo 8 2V min.; Veo max. Curren teary eit aa eae 2.7 = 20uA max, 5.5V = 1mA max. Lagie 0 Input: WiolTROS, jg ie Pea ie eo ae oa . 8V max. LRP RTE: ots Gm aig las wale grea ieee ae -.6mA max. Lagi 1 Voltage out .. 2. 2. 27V min, Logie 0 Voltage-oute sa eas 5V max. Operating temperature range: ...... Oto FOC Storage temperature:, 2 2. es .. 85 to +125C. * Delays increase or decrease approximately 2% for a respective increase or decrease of 5% in supply voltage. PART NUMBER TABLE Suffix Part Number with G (for Gull Wing Lead), J (for J Lead), F (for Thru-hole Lead} or T (for Tucked Lead). Examples: SS2FLDL-TTL-10G (Gull Wing), $S2FLDL-TTL- 25 (J Lead), SS2FLDL-TTL-70F (Thru-hole Lead) or $S2FLDL-TTL-10T (Tucked Lead). DELAYS AND TOLERANCES (in ns) PART NO. OUTPUT PART NO. OUTPUT $52FLDL-TTL-5 +.5 S52FLDL-TTL-30 30 21.5 SS2FLDL-TTL-6 625 SS2FLBL-TTL-35 35 41.5 SS2FLDL-TTL-? 725 $52FLDL-TTL-40 40 41.5 S52FLDL-TTL-6 B +5 S52FLDL-TTL-45 45 +2 SS2FLDL-TTL-9 94,5 S52FLDL-TTL-50 50 +2 SS2FLDL-TTL-10 | 104.5 So2FLDL-TTL-55 55 +2 SS2FLDL-TTL-11 | 112.75 || SS2FLDL-TTL-60 60 +2 SS@FLDL-TTL-12 | 124.75 || SS2FLOL-TTL-65 65 42.5 SS@FLDL-TTL-13 | 134.75 || SS2FLOL-TTL-70 70 42.5 SS@FLDL-TTL-14 | 144.75 || SS2FLOL-TTL-75 75 42.5 SS2FLDL-TTL-15 | 154.75 || SS2FLDL-TTL-80 80 +2.5 SS2FLDL-TTL-16 | 164.75 |) SS2FLDL-TTL-85 85 +4 SS2FLDL-TTL-17 | 17 4.75 || SS2FLDL-TTL-90 90 +3 SS@FLDOL-TTL-18 | 184.75 || SS2FLDL-TTL-95 95 44 SS2FLBL-TTL-19 | 194.75 || SS2FLDL-TTL-100 | 100 43 SS2FLDL-TTL-20 | 204.75 || SS2FLDL-TTL-125 | 125 +4 SS2FLBL-TTL-21 | 21 +1 So2FLDL-TTL-150 | 150 24.5 SS2FLBL-TTL-22 | 22 +1 So2FLDL-TTL-175 | 175 +5 SS2FLBL-TTL-23 | 23 +1 SS2FLDL-TTL-200 | 200 +6 SS2FLDL-TTL-24 | 24 41 SS2FLDL-TTL-225 | 225 47 SS2FLDL-TTL-25 | 2544 So2FLDL-TTL-250 | 250 +8 @.,4ll modules can be operated with a minimum input pulse width of 100% of fulldelay and pulse period approaching square wave; since delay accuracies may be somewhat degraded, it is suggested that the module be evaluated under the intended specific operating conditions. Special modules can be readily manufactured toimprove accuracies and/or provide customer specified random delay times for specilic applications. Catalog No. C/122092