DIE Digital Arithmetic Circuits 8
| Part | RoHS | Manufacturer | Logic IC Type | Temperature Grade | Terminal Form | No. of Terminals | Package Code | Package Shape | Total Dose (V) | Package Body Material | Schmitt Trigger | Surface Mount | No. of Functions | Technology | Screening Level | No. of Bits | Packing Method | Nominal Supply Voltage / Vsup (V) | Power Supplies (V) | Load Capacitance (CL) | Package Style (Meter) | Package Equivalence Code | Propagation Delay (tpd) | 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 |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
|
Texas Instruments |
IDENTITY COMPARATOR |
MILITARY |
NO LEAD |
20 |
DIE |
UNSPECIFIED |
UNSPECIFIED |
YES |
1 |
CMOS |
8 |
UNCASED CHIP |
255 ns |
125 Cel |
-55 Cel |
UPPER |
X-XUUC-N20 |
6 V |
Not Qualified |
INVERTED |
2 V |
CASCADABLE |
HC/UH |
|||||||||||||||||||||||
|
Texas Instruments |
MAGNITUDE COMPARATOR |
MILITARY |
NO LEAD |
16 |
DIE |
RECTANGULAR |
UNSPECIFIED |
YES |
1 |
CMOS |
4 |
5 |
UNCASED CHIP |
600 ns |
125 Cel |
-55 Cel |
UPPER |
R-XUUC-N16 |
18 V |
Not Qualified |
TRUE |
3 V |
CASCADABLE |
4000/14000/40000 |
||||||||||||||||||||||
|
Texas Instruments |
ENCODER |
MILITARY |
NO LEAD |
16 |
DIE |
RECTANGULAR |
UNSPECIFIED |
YES |
1 |
CMOS |
8 |
5 |
UNCASED CHIP |
440 ns |
125 Cel |
-55 Cel |
UPPER |
R-XUUC-N16 |
18 V |
Not Qualified |
INVERTED |
3 V |
8 TO 3 LINE PRIORITY ENCODER |
4000/14000/40000 |
||||||||||||||||||||||
|
Texas Instruments |
ENCODER |
MILITARY |
NO LEAD |
16 |
DIE |
RECTANGULAR |
UNSPECIFIED |
YES |
1 |
CMOS |
10 |
5 |
UNCASED CHIP |
900 ns |
125 Cel |
-55 Cel |
UPPER |
R-XUUC-N16 |
18 V |
Not Qualified |
INVERTED |
3 V |
10 TO 4 LINE PRIORITY ENCODER |
4000/14000/40000 |
||||||||||||||||||||||
|
Texas Instruments |
MAGNITUDE COMPARATOR |
MILITARY |
NO LEAD |
16 |
DIE |
RECTANGULAR |
UNSPECIFIED |
YES |
1 |
CMOS |
4 |
5 |
UNCASED CHIP |
1250 ns |
125 Cel |
-55 Cel |
UPPER |
R-XUUC-N16 |
18 V |
Not Qualified |
TRUE |
3 V |
CASCADABLE |
4000/14000/40000 |
||||||||||||||||||||||
|
Renesas Electronics |
ERROR DETECTION AND CORRECTION CIRCUIT |
NO LEAD |
28 |
DIE |
RECTANGULAR |
300k Rad(Si) |
UNSPECIFIED |
YES |
1 |
CMOS |
MIL-PRF-38535 Class V |
16 |
5 |
UNCASED CHIP |
37 ns |
3-STATE |
UPPER |
R-XUUC-N28 |
5.5 V |
Not Qualified |
4.5 V |
AC |
||||||||||||||||||||||||
|
Renesas Electronics |
ERROR DETECTION AND CORRECTION CIRCUIT |
MILITARY |
NO LEAD |
28 |
DIE |
UNSPECIFIED |
UNSPECIFIED |
YES |
1 |
CMOS |
16 |
5 |
UNCASED CHIP |
125 Cel |
3-STATE |
-55 Cel |
UPPER |
X-XUUC-N28 |
5.5 V |
Not Qualified |
4.5 V |
ACT |
||||||||||||||||||||||||
|
Renesas Electronics |
MAGNITUDE COMPARATOR |
MILITARY |
NO LEAD |
16 |
DIE |
UNSPECIFIED |
UNSPECIFIED |
YES |
1 |
CMOS |
4 |
5 |
50 pF |
UNCASED CHIP |
66 ns |
125 Cel |
-55 Cel |
UPPER |
X-XUUC-N16 |
5.5 V |
Not Qualified |
TRUE |
4.5 V |
CASCADABLE |
HCT |
Digital arithmetic circuits are electronic circuits designed to perform arithmetic operations on digital signals. These circuits are essential components of digital systems, such as microprocessors, digital signal processors, and programmable logic devices.
Digital arithmetic circuits can perform various arithmetic operations, including addition, subtraction, multiplication, division, and modulo arithmetic. These operations are performed using binary arithmetic, where numbers are represented using the binary number system (0s and 1s).
Adders are one of the most commonly used digital arithmetic circuits. They are used to perform binary addition, where two binary numbers are added to produce a sum. Adders can be designed using various techniques, including ripple carry adders, carry look-ahead adders, and carry select adders.
Subtractors are also commonly used digital arithmetic circuits. They are used to perform binary subtraction, where one binary number is subtracted from another to produce a difference. Subtractors can be designed using techniques, including ripple borrow subtractors, borrow look-ahead subtractors, and borrow select subtractors.
Multiplexers and demultiplexers are digital circuits that can be used for various arithmetic operations, such as multiplication and division. Multiplexers can be used to select one of several input signals based on a control signal, while demultiplexers can be used to distribute a single input signal to several outputs based on a control signal.
Digital arithmetic circuits can also be designed using programmable logic devices, such as field-programmable gate arrays (FPGAs) and complex programmable logic devices (CPLDs). These devices can be programmed to implement various arithmetic operations and can be reprogrammed to adapt to changing system requirements.