LOGIC DELAY LINES
 MSFLDL-XX
Mini SIP
FAST TTL Logic Delay Line
- T²L FAST input and output
- Delay stable and precise
- 5-pin SIP package (.350 high)
- Available in delays from 5 to 500ns
- Output isolated and with 10 T²L fan-out capacity
- Rise time 4ns maximum
DESIGN NOTES
The "Mini Sip Series" Logic Delay Lines developed by Engineered Components Company have been designed to provide precise delays with required driving and pick-off circuitry contained in a 5-pin SIP package compatible with T²L FAST circuits. These logic delay lines are of hybrid construction utilizing the proven technologies of active integrated circuitry and of passive networks utilizing capacitive, inductive and resistive elements. The MTBF on these modules, when calculated per MIL-HDBK-217 for a 50°C ground fixed environment, is in excess of 3 million hours. Module design includes compensation for propagation delays and incorporates internal termination at the output; no additional external components are needed to obtain the desired delay.
The MSFLDL-TTL is offered in 48 delays from 5ns to 500ns. Delay tolerances are maintained as shown in the accompanying part number table, when tested under the "Test Conditions" shown. Delay time is measured at the +1.5V level on the leading edge. Rise time for all modules is 4ns maximum when measured from 0.75V to 2.4V. Temperature coefficient of delay is approximately +1200 ppm/°C over the operating temperature range of 0°to +70°C.
These modules accept either logic "1" or logic "0" inputs and reproduce the logic at the output without inversion. The delay modules are intended primarily for use with positive going pulses and are calibrated to the tolerances shown in the table on rising edge delay; where best accuracy is desired in applications using falling edge timing, it is recommended that a special unit be calibrated for the specific application. Each module has the capability of driving up to 10 T²L loads.
These "Mini SIP Series" modules
are packaged in a 5-pin SIP housing, molded of flame-proof
Diallyl Phthalate per ASTM D 5948, Type SDG-F, and are fully
encapsulated in epoxy resin. Leads meet the solderability
requirements of MIL-STD-202, Method 208. Corner standoffs
on the housing provide positive standoff from the printed
circuit board to permit solder-fillet formation and flush
cleaning of solder-flux residues for improved reliability.
Marking consists of manufacturer's
logo (EC²),
part number, pin one (1) identification and date code of
manufacture. All marking is applied by silk screen process
using white epoxy paint in accordance with MIL-STD-130,
to meet the permanency of identification required by MIL-STD-202,
Method 215.
TEST CONDITIONS
1. All measurements are made at 25°C.
2. Vcc supply voltage is maintained at 5.0V DC.
3. All units are tested using a FAST toggle-type positive input pulse and one FAST load at the output.
4. 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
Vcc supply voltage: ............. 4.75 to 5.25V DC
Vcc supply current:
Constant "0" in .............. 60mA typical
Constant "1" in .............. 7mA typical
Logic 1 Input:
Voltage ...................... 2V min.; Vcc max.
Current ...................... 2.7V = 20uA max.
5.5V = 1mA max.
Logic 0 Input:
Voltage ...................... 0.8V max.
Current ...................... -.6mA max.
Logic 1 Voltage out: ............ 2.7V min.
Logic 0 Voltage out: ............ 0.5V max.
Operating temperature range: .... 0 to 70°C.
Storage temperature: ............ -55 to +125°C.
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*Delays increase or decrease approximately 4% for a respective increase or decrease of 5% in supply voltage.
PART NUMBER TABLE
DELAYS AND
TOLERANCES (in ns)
| PART NUMBER |
OUTPUT |
MSFLDL-TTL-5
MSFLDL-TTL-6
MSFLDL-TTL-7
MSFLDL-TTL-8
MSFLDL-TTL-9
MSFLDL-TTL-10
MSFLDL-TTL-11
MSFLDL-TTL-12
MSFLDL-TTL-13
MSFLDL-TTL-14
MSFLDL-TTL-15
MSFLDL-TTL-16
MSFLDL-TTL-17
MSFLDL-TTL-18
MSFLDL-TTL-19
MSFLDL-TTL-20
MSFLDL-TTL-21
MSFLDL-TTL-22
MSFLDL-TTL-23
MSFLDL-TTL-24
MSFLDL-TTL-25
MSFLDL-TTL-30
MSFLDL-TTL-35
MSFLDL-TTL-40
MSFLDL-TTL-45
MSFLDL-TTL-50
MSFLDL-TTL-55
MSFLDL-TTL-60
MSFLDL-TTL-65
MSFLDL-TTL-70
MSFLDL-TTL-75
MSFLDL-TTL-80
MSFLDL-TTL-85
MSFLDL-TTL-90
MSFLDL-TTL-95
MSFLDL-TTL-100
MSFLDL-TTL-125
MSFLDL-TTL-150
MSFLDL-TTL-175
MSFLDL-TTL-200
MSFLDL-TTL-225
MSFLDL-TTL-250
MSFLDL-TTL-275
MSFLDL-TTL-300
MSFLDL-TTL-350
MSFLDL-TTL-400
MSFLDL-TTL-450
MSFLDL-TTL-500 |
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5±1.0
6±1.0
7±1.0
8±1.0
9±1.0
10±1.0
11±1.0
12±1.0
13±1.0
14±1.0
15±1.0
16±1.0
17±1.0
18±1.0
19±1.0
20±1.0
21±1.0
22±1.0
23±1.0
24±1.0
25±1.0
30±1.5
35±1.5
40±1.5
45±2.0
50±2.0
55±2.0
60±2.0
65±2.5
70±2.5
75±2.5
80±2.5
85±3.0
90±3.0
95±3.0
100±3.0
125±4.0
150±4.5
175±5.0
200±6.0
225±7.0
250±8.0
275±9.0
300±10.0
350±11.0
400±12.0
450±14.0
500±15.0 |
All modules can be operated
with a minimum input pulse width of 100% of full delay 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 to improve accuracies and/or provide customer
specified delay times for specific applications.
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