DIP Delay Lines 8
| Part | RoHS | Manufacturer | Logic IC Type | Temperature Grade | Terminal Form | No. of Terminals | Package Code | Package Shape | Package Body Material | Nominal Total Delay (td) | Surface Mount | No. of Functions | No. of Taps/Steps | Technology | Screening Level | Nominal Output Impedance (Z0) | Programmable Delay Line | Packing Method | Nominal Supply Voltage / Vsup (V) | Power Supplies (V) | Load Capacitance (CL) | Package Style (Meter) | Package Equivalence Code | Maximum I (ol) | Sub-Category | Terminal Pitch | Maximum Operating Temperature | Output Characteristics | Minimum Operating Temperature | Terminal Finish | Terminal Position | JESD-30 Code | Moisture Sensitivity Level (MSL) | Maximum Supply Voltage (Vsup) | Maximum Seated Height | Width | Qualification | Output Polarity | Minimum Supply Voltage (Vsup) | Maximum Power Supply Current (ICC) | Additional Features | JESD-609 Code | Maximum Time At Peak Reflow Temperature (s) | Peak Reflow Temperature (C) | Length | Family | Maximum Input Frequency (fmax) |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Datatronics |
ACTIVE DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
4 ns |
NO |
1 |
5 |
NO |
5 |
5 |
IN-LINE |
DIP8/16,.3 |
Delay Lines |
2.54 mm |
70 Cel |
0 Cel |
DUAL |
R-PDIP-T8 |
5.25 V |
8 mm |
10.16 mm |
Not Qualified |
INVERTED |
4.75 V |
32 mA |
22.86 mm |
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|
Datatronics |
ACTIVE DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
5 ns |
NO |
1 |
5 |
NO |
5 |
5 |
IN-LINE |
DIP8/16,.3 |
Delay Lines |
2.54 mm |
70 Cel |
0 Cel |
DUAL |
R-PDIP-T8 |
5.25 V |
8 mm |
10.16 mm |
Not Qualified |
INVERTED |
4.75 V |
32 mA |
22.86 mm |
|||||||||||||||||
|
Datatronics |
ACTIVE DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
6 ns |
NO |
1 |
5 |
NO |
5 |
5 |
IN-LINE |
DIP8/16,.3 |
Delay Lines |
2.54 mm |
70 Cel |
0 Cel |
DUAL |
R-PDIP-T8 |
5.25 V |
8 mm |
10.16 mm |
Not Qualified |
INVERTED |
4.75 V |
32 mA |
22.86 mm |
|||||||||||||||||
|
Lexor |
ACTIVE DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
150 ns |
NO |
1 |
5 |
TTL |
NO |
5 |
IN-LINE |
DIP8/14,.3 |
2.54 mm |
70 Cel |
0 Cel |
DUAL |
R-PDIP-T14 |
5.25 V |
7.62 mm |
TRUE |
4.75 V |
21 mm |
84309 |
||||||||||||||||||||
|
Lexor |
ACTIVE DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
500 ns |
NO |
1 |
5 |
TTL |
NO |
5 |
IN-LINE |
DIP8/14,.3 |
2.54 mm |
70 Cel |
0 Cel |
DUAL |
R-PDIP-T14 |
5.25 V |
7.62 mm |
TRUE |
4.75 V |
21 mm |
84316 |
||||||||||||||||||||
|
Maxim Integrated |
SILICON DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
NO |
1 |
5 |
CMOS |
NO |
5 |
IN-LINE |
2.54 mm |
70 Cel |
0 Cel |
TIN LEAD |
DUAL |
R-PDIP-T8 |
5.25 V |
4.572 mm |
7.62 mm |
Not Qualified |
TRUE |
4.75 V |
e0 |
20 |
240 |
9.375 mm |
CMOS |
||||||||||||||||
|
Maxim Integrated |
SILICON DELAY LINE |
INDUSTRIAL |
THROUGH-HOLE |
8 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
30 ns |
NO |
3 |
1 |
CMOS |
NO |
5 |
5 |
IN-LINE |
DIP8,.3 |
Delay Lines |
2.54 mm |
85 Cel |
-40 Cel |
TIN LEAD |
DUAL |
R-PDIP-T8 |
5.25 V |
4.572 mm |
7.62 mm |
Not Qualified |
TRUE |
4.75 V |
70 mA |
BOTH LEADING & TRAILING EDGE ACCURACY |
e0 |
245 |
9.375 mm |
1013 |
|||||||||||
|
Maxim Integrated |
SILICON DELAY LINE |
COMMERCIAL |
THROUGH-HOLE |
14 |
DIP |
RECTANGULAR |
PLASTIC/EPOXY |
1000 ns |
NO |
1 |
10 |
CMOS |
NO |
5 |
IN-LINE |
2.54 mm |
70 Cel |
0 Cel |
TIN LEAD |
DUAL |
R-PDIP-T14 |
5.25 V |
4.572 mm |
7.62 mm |
Not Qualified |
TRUE |
4.75 V |
e0 |
20 |
240 |
19.05 mm |
1010 |
A delay line is an electronic component used in digital systems to introduce a delay or a time lag in a signal. Delay lines are commonly used in digital systems that require precise timing, synchronization, or control of signals.
Delay lines can be passive or active, depending on the method used to introduce the delay in the signal. Passive delay lines use passive components, such as capacitors, inductors, and resistors, to introduce the delay in the signal. Active delay lines use active components, such as amplifiers, to introduce the delay in the signal.
Delay lines can also be fixed or variable, depending on whether the delay introduced in the signal is fixed or can be adjusted. Fixed delay lines introduce a fixed delay in the signal, while variable delay lines can be adjusted to introduce a variable delay in the signal.
Delay lines are often used in digital systems that require precise timing or synchronization between different components or devices. For example, in a memory system, a delay line may be used to ensure that the signals sent to and received from the memory chips are synchronized and aligned with the clock signal.
Delay lines can also be used to compensate for signal propagation delays caused by long transmission lines or cables. In this case, the delay line is used to introduce a delay in the signal to compensate for the delay caused by the transmission line or cable.