The following is a list of 7400 series digital logic integrated circuits. The SN7400 series originated with TTL integrated circuits made by Texas Instruments. Because of the popularity of these parts, they were second-sourced by other manufacturers who kept the 7400 sequence number as an aid to identification of compatible parts. As well, compatible TTL parts originated by other manufacturers were second sourced in the TI product line under a 74xxx series part number.
Just the base numbers are listed below, that is: parts are listed here as if made in the basic, standard power and speed, TTL form, although many later parts were never manufactured with that technology.
7400: Quad 2-input NAND gate
7401: Quad 2-input NAND gate with open collector outputs
7402: Quad 2-input NOR gate
7403: Quad 2-input NAND gate with open collector outputs (different pinout than 7401)
7404: Hex Inverter
7405: Hex Inverter with open collector outputs
7406: Hex Inverter Buffer/Driver with 30V open collector outputs
7407: Hex Buffer/Driver with 30V open collector outputs
7408: Quad 2-input AND gate
7409: Quad 2-input AND gate with open collector outputs
7410: Triple 3-input NAND gate
7411: Triple 3-input AND gate
7412: Triple 3-input NAND gate with open collector outputs
7413: Dual Schmitt trigger 4-input NAND gate
7414: Hex Schmitt trigger Inverter
7415: Triple 3-input AND gate with open collector outputs
7416: Hex Inverter Buffer/Driver with 15V open collector outputs
7417: Hex Buffer/Driver with 15V open collector outputs
7418: Dual 4-input NAND gate with schmitt trigger inputs
7419: Hex Schmitt trigger Inverter
7420: Dual 4-input NAND gate
7421: Dual 4-input AND gate
7422: Dual 4-Input NAND gate with open collector outputs
7423: Expandable Dual 4-input NOR gate with strobe
7424: Quad 2-input NAND gate gates with Schmitt-trigger line-receiver inputs.
7425: Dual 4-input NOR gate with Strobe
7426: Quad 2-input NAND gate with 15V open collector outputs
7427: Triple 3-input NOR gate
7428: Quad 2-input NOR Buffer
7430: 8-input NAND gate
7431: Hex Delay Elements
7432: Quad 2-input OR gate
7433: Quad 2-input NOR Buffer with open collector outputs
7436: Quad 2-input NOR Gate (different pinout than 7402)
7437: Quad 2-input NAND Buffer
7438: Quad 2-input NAND Buffer with open collector outputs
7439: Quad 2-input NAND Buffer
7440: Dual 4-input NAND Buffer
7441: Binary-coded decimal to Decimal Decoder/Nixie tube Driver
7442: BCD to Decimal Decoder
7443: Excess-3 to Decimal Decoder
7444: Excess-3-Gray code to Decimal Decoder
7445: BCD to Decimal Decoder/Driver
7446: BCD to Seven-segment display Decoder/Driver with 30V open collector outputs
7447: BCD to 7-segment Decoder/Driver with 15V open collector outputs
7448: BCD to 7-segment Decoder/Driver with Internal Pullups
7449: BCD to 7-segment Decoder/Driver with open collector outputs
7450: Dual 2-Wide 2-input AND-OR-Invert Gate (one gate expandable)
7451: Dual 2-Wide 2-Input AND-OR-Invert Gate
7452: Expandable 4-Wide 2-input AND-OR Gate
7453: Expandable 4-Wide 2-input AND-OR-Invert Gate
7454: 4-Wide 2-Input AND-OR-Invert Gate
7455: 2-Wide 4-Input AND-OR-Invert Gate (74H version is expandable)
7456: 50:1 Frequency divider
7457: 60:1 Frequency divider
7458: 2-Input & 3-Input AND-OR Gate
7459: 2-Input & 3-Input AND-OR-Invert Gate
7460: Dual 4-input Expander
7461: Triple 3-input Expander
7462: 3-2-2-3-Input AND-OR Expander
7463: Hex Current Sensing Interface Gates
7464: 4-2-3-2-Input AND-OR-Invert Gate
7465: 4-2-3-2 Input AND-OR-Invert Gate with open collector output
7468: Dual 4 Bit Decade Counters
7469: Dual 4 Bit Binary Counters
7470: AND-Gated Positive Edge Triggered J-K Flip-Flop with Preset and Clear
74H71: AND-OR-Gated J-K Master-Slave Flip-Flop with Preset
74L71: AND-Gated R-S Master-Slave Flip-Flop with Preset and Clear
7472: AND Gated J-K Master-Slave Flip-Flop with Preset and Clear
7473: Dual J-K Flip-Flop with Clear
7474: Dual D Positive Edge Triggered Flip-Flop with Preset and Clear
7475: 4-bit Bistable Latch
7476: Dual J-K Flip-Flop with Preset and Clear
7477: 4-bit Bistable Latch
74H78, 74L78: Dual J-K Flip-Flop with Preset, Common Clear, and Common Clock
74LS78A: Dual Negative Edge Triggered J-K Flip-Flop with Preset, Common Clear, and Common Clock
7479: Dual D Flip-Flop
7480: Gated Full Adder
7481: 16-bit Random Access Memory
7482: 2-bit Binary Full Adder
7483: 4-bit Binary Full Adder
7484: 16-bit Random Access Memory
7485: 4-bit Magnitude Comparator
7486: Quad 2-input XOR gate
7487: 4-bit True/Complement/Zero/One Element
7488: 256-bit Read-only memory
7489: 64-bit Random Access Memory
7490: Decade Counter (separate Divide-by-2 and Divide-by-5 sections)
7491: 8-bit Shift Register, Serial In, Serial Out, Gated Input
7492: Divide-by-12 Counter (separate Divide-by-2 and Divide-by-6 sections)
7493: 4-bit Binary Counter (separate Divide-by-2 and Divide-by-8 sections)
7494: 4-bit Shift register, Dual Asynchronous Presets
7495: 4-bit Shift register, Parallel In, Parallel Out, Serial Input
7496: 5-bit Parallel-In/Parallel-Out Shift register, Asynchronous Preset
7497: Synchronous 6-bit Binary Rate Multiplier
7498: 4-bit Data Selector/Storage Register
7499: 4-bit Bidirectional Universal Shift register
74100: Dual 4-Bit Bistable Latch
74101: AND-OR-Gated J-K Negative-Edge-Triggered Flip-Flop with Preset
74102: AND-Gated J-K Negative-Edge-Triggered Flip-Flop with Preset and Clear
74103: Dual J-K Negative-Edge-Triggered Flip-Flop with Clear
74104: J-K Master-Slave Flip-Flop
74105: J-K Master-Slave Flip-Flop
74106: Dual J-K Negative-Edge-Triggered Flip-Flop with Preset and Clear
74107: Dual J-K Flip-Flop with Clear
74107A: Dual J-K Negative-Edge-Triggered Flip-Flop with Clear
74108: Dual J-K Negative-Edge-Triggered Flip-Flop with Preset, Common Clear, and Common Clock
74109: Dual J-Not-K Positive-Edge-Triggered Flip-Flop with Clear and Preset
74110: AND-Gated J-K Master-Slave Flip-Flop with Data Lockout
74111: Dual J-K Master-Slave Flip-Flop with Data Lockout
74112: Dual J-K Negative-Edge-Triggered Flip-Flop with Clear and Preset
74113: Dual J-K Negative-Edge-Triggered Flip-Flop with Preset
74114: Dual J-K Negative-Edge-Triggered Flip-Flop with Preset, Common Clock and Clear
74116: Dual 4-bit Latches with Clear
74118: Hex Set/Reset Latch
74119: Hex Set/Reset Latch
74120: Dual Pulse Synchronizer/Drivers
74121: Monostable Multivibrator
74122: Retriggerable Monostable Multivibrator with Clear
74123: Dual Retriggerable Monostable Multivibrator with Clear
74124: Dual Voltage-Controlled Oscillator
74125: Quad Bus Buffer with Three-State Outputs, Negative Enable
74126: Quad Bus Buffer with Three-state Outputs, Positive Enable
74128: Quad 2-input NOR Line Driver
74130: Quad 2-input AND gate Buffer with 30V open collector outputs
74131: Quad 2-input AND gate Buffer with 15V open collector outputs
74132: Quad 2-input NAND Schmitt trigger
74133: 13-Input NAND gate
74134: 12-Input NAND gate with Three-state Output
74135: Quad Exclusive-OR/NOR Gate
74136: Quad 2-Input XOR gate with open collector outputs
74137: 3 to 8-line Decoder/Demultiplexer with Address Latch
74138: 3 to 8-line Decoder/Demultiplexer
74139: Dual 2 to 4-line Decoder/Demultiplexer
74140: Dual 4-input NAND Line Driver
74141: BCD to Decimal Decoder/Driver for cold-cathode indicator/NIXIE Tube
74142: Decade Counter/Latch/Decoder/Driver for Nixie Tubes
74143: Decade Counter/Latch/Decoder/7-segment Driver, 15 mA Constant Current
74144: Decade Counter/Latch/Decoder/7-segment Driver, 15V open collector outputs
74145: BCD to Decimal Decoder/Driver
74147: 10-Line to 4-Line Priority Encoder
74148: 8-Line to 3-Line Priority Encoder
74150: 16-Line to 1-Line Data Selector/Multiplexer
74151: 8-Line to 1-Line Data Selector/Multiplexer
74152: 8-Line to 1-Line Data Selector/Multiplexer
74153: Dual 4-Line to 1-Line Data Selector/Multiplexer
74154: 4-Line to 16-Line Decoder/Demultiplexer
74155: Dual 2-Line to 4-Line Decoder/Demultiplexer
74156: Dual 2-Line to 4-Line Decoder/Demultiplexer with open collector outputs
74157: Quad 2-Line to 1-Line Data Selector/Multiplexer, Noninverting
74158: Quad 2-Line to 1-Line Data Selector/Multiplexer, Inverting
74159: 4-Line to 16-Line Decoder/Demultiplexer with open collector outputs
74160: Synchronous 4-bit Decade Counter with Asynchronous Clear
74161: Synchronous 4-bit Binary Counter with Asynchronous Clear
74162: Synchronous 4-bit Decade Counter with Synchronous Clear
74163: Synchronous 4-bit Binary Counter with Synchronous Clear
74164: 8-bit Parallel-Out Serial Shift Register with Asynchronous Clear
74165: 8-bit Serial Shift Register, Parallel Load, Complementary Outputs
74166: Parallel-Load 8-Bit Shift Register
74167: Synchronous Decade Rate Multiplier
74168: Synchronous 4-Bit Up/Down Decade Counter
74169: Synchronous 4-Bit Up/Down Binary Counter
74170: 4 by 4 Register File with open collector outputs
74172: 16-Bit Multiple Port Register File with Three-state Outputs
74173: Quad D Flip-Flop with Three-state Outputs
74174: Hex D Flip-Flop with Common Clear
74175: Quad D Edge-Triggered Flip-Flop with Complementary Outputs and Asynchronous Clear
74176: Presettable Decade (Bi-Quinary) Counter/Latch
74177: Presettable Binary Counter/Latch
74178: 4-bit Parallel-Access Shift Register
74179: 4-bit Parallel-Access Shift Register with Asynchronous Clear and Complementary QD Outputs
74180: 9-bit Odd/Even Parity bit Generator and Checker
74181: 4-bit Arithmetic Logic Unit and Function Generator
74182: Lookahead Carry Generator
74183: Dual Carry-Save Full adder
74184: BCD to Binary Converter
74185: Binary to BCD Converter
74186: 512-bit (64x8) Read-only memory with open collector outputs
74187: 1024-bit (256x4) Read only memory with open collector outputs
74188: 256-bit (32x8) Programmable read-only memory with open collector outputs
74189: 64-bit (16x4) RAM with Inverting three-state Outputs
74190: Synchronous Up/Down Decade Counter
74191: Synchronous Up/Down Binary Counter
74192: Synchronous Up/Down Decade Counter with Clear
74193: Synchronous Up/Down Binary Counter with Clear
74194: 4-bit Bidirectional Universal Shift Register
74195: 4-bit Parallel-Access Shift Register
74196: Presettable Decade Counter/Latch
74197: Presettable Binary Counter/Latch
74198: 8-bit Bidirectional Universal Shift Register
74199: 8-bit Bidirectional Universal Shift Register with J-Not-K Serial Inputs
74200: 256-bit RAM with Three-state Outputs
74201: 256-bit (256x1) RAM with three-state outputs
74206: 256-bit RAM with open collector outputs
74209: 1024-bit (1024x1) RAM with three-state output
74210: Octal Buffer
74219: 64-bit (16x4) RAM with Noninverting three-state outputs
74221: Dual Monostable Multivibrator with Schmitt trigger input
74222: 16 by 4 Synchronous FIFO Memory with three-state outputs
74224: 16 by 4 Synchronous FIFO Memory with three-state outputs
74225: Asynchronous 16x5 FIFO Memory
74226: 4-bit Parallel Latched Bus Transceiver with three-state outputs
74230: Octal Buffer/Driver with three-state outputs
74232: Quad NOR Schmitt trigger
74237: 1-of-8 Decoder/Demultiplexer with Address Latch, Active High Outputs
74238: 1-of-8 Decoder/Demultiplexer, Active High Outputs
74239: Dual 2-of-4 Decoder/Demultiplexer, Active High Outputs
74240: Octal Buffer with Inverted three-state outputs
74241: Octal Buffer with Noninverted three-state outputs
74242: Quad Bus Transceiver with Inverted three-state outputs
74243: Quad Bus Transceiver with Noninverted three-state outputs
74244: Octal Buffer with Noninverted three-state outputs
74245: Octal Bus Transceiver with Noninverted three-state outputs
74246: BCD to 7-segment Decoder/Driver with 30V open collector outputs
74247: BCD to 7-segment Decoder/Driver with 15V open collector outputs
74248: BCD to 7-segment Decoder/Driver with Internal Pull-up Outputs
74249: BCD to 7-segment Decoder/Driver with open collector outputs
74251: 8-line to 1-line Data Selector/Multiplexer with complementary three-state outputs
74253: Dual 4-line to 1-line Data Selector/Multiplexer with three-state outputs
74255: Dual 4-bit Addressable Latch
74256: Dual 4-bit Addressable Latch
74257: Quad 2-line to 1-line Data Selector/Multiplexer with Noninverted three-state outputs
74258: Quad 2-line to 1-line Data Selector/Multiplexer with Inverted three-state outputs
74259: 8-bit Addressable Latch
74260: Dual 5-Input NOR Gate
74261: 2-bit by 4-bit Parallel Binary Multiplier
74265: Quad Complementary Output Elements
74266: Quad 2-Input XNOR gate with open collectorOutputs
74270: 2048-bit (512x4) Read Only Memory with open collector outputs
74271: 2048-bit (256x8) Read Only Memory with open collector outputs
74273: 8-bit Register with Reset
74274: 4-bit by 4-bit Binary Multiplier
74275: 7-bit Slice Wallace tree
74276: Quad J-Not-K Edge-Triggered Flip-Flops with Separate Clocks, Common Preset and Clear
74278: 4-bit Cascadeable Priority Registers with Latched Data Inputs
74279: Quad Set-Reset Latch
74280: 9-bit Odd/Even Parity bit Generator/Checker
74281: 4-bit Parallel Binary Accumulator
74283: 4-bit Binary Full adder
74284: 4-bit by 4-bit Parallel Binary Multiplier (low order 4 bits of product)
74285: 4-bit by 4-bit Parallel Binary Multiplier (high order 4 bits of product)
74287: 1024-bit (256x4) Programmable read-only memory with three-state outputs
74288: 256-bit (32x8) Programmable read-only memory with three-state outputs
Half adder
A half adder is a logical circuit that performs an addition operation on two one-bit binary numbers often written as A and B. The half adder output is a sum of the two inputs usually represented with the signals Cout and S where . Following is the logic table for a half adder:
Inputs Outputs
A B C S
0 0 0 0
0 1 0 1
1 0 0 1
1 1 1 0
Example half adder circuit diagramAs an example, a Half Adder can be built with an XOR gate and an AND gate.
___________
A ------
Half
-----
Adder
-----
B ------
___________
[edit] Full adder
Schematic symbol for a 1-bit full adder with Cin and Cout drawn on sides of block to emphasize their use in a multi-bit adder.A full adder is a logical circuit that performs an addition operation on three one-bit binary numbers often written as A, B, and Cin. The full adder produces a two-bit output sum typically represented with the signals Cout and S where . The full adder's truth table is:
Inputs Outputs
A B Ci Co S
0 0 0 0 0
1 0 0 0 1
0 1 0 0 1
1 1 0 1 0
0 0 1 0 1
1 0 1 1 0
0 1 1 1 0
1 1 1 1 1
A full adder can be implemented in many different ways such as with a custom transistor-level circuit or composed of other gates. One example implementation is with and .
Example full adder circuit diagram
Inputs: {A, B, Cin} → Outputs: {S, Cout}File:Full Adder.JPG
Example full adder circuit diagram using only NAND and XOR gates
Inputs: {A, B, Cin} → Outputs: {S, Cout}In this implementation, the final OR gate before the carry-out output may be replaced by an XOR gate without altering the resulting logic. Using only two types of gates is convenient if the circuit is being implemented using simple IC chips which contain only one gate type per chip.
A full adder can be constructed from two half adders by connecting A and B to the input of one half adder, connecting the sum from that to an input to the second adder, connecting Ci to the other input and OR the two carry outputs. Equivalently, S could be made the three-bit XOR of A, B, and Ci, and Co could be made the three-bit majority function of A, B, and Ci.
[edit] Multiple-bit adders
[edit] Ripple carry adder
It is possible to create a logical circuit using multiple full adders to add N-bit numbers. Each full adder inputs a Cin, which is the Cout of the previous adder. This kind of adder is a ripple carry adder, since each carry bit "ripples" to the next full adder. Note that the first (and only the first) full adder may be replaced by a half adder.
The layout of ripple carry adder is simple, which allows for fast design time; however, the ripple carry adder is relatively slow, since each full adder must wait for the carry bit to be calculated from the previous full adder. The gate delay can easily be calculated by inspection of the full adder circuit. Each full adder requires three levels of logic. In a 32-bit [ripple carry] adder, there are 32 full adders, so the critical path (worst case) delay is 31 * 2(for carry propagation) + 3(for sum) = 65 gate delays.
[edit] Carry look-ahead adders
Main article: Carry look-ahead adder
To reduce the computation time, engineers devised faster ways to add two binary numbers by using carry lookahead adders. They work by creating two signals (P and G) for each bit position, based on whether a carry is propagated through from a less significant bit position (at least one input is a '1'), a carry is generated in that bit position (both inputs are '1'), or if a carry is killed in that bit position (both inputs are '0'). In most cases, P is simply the sum output of a half-adder and G is the carry output of the same adder. After P and G are generated the carries for every bit position are created. Some advanced carry look ahead architectures are the Manchester carry chain, Brent-Kung adder, and the Kogge-Stone adder.
4-bit adder with Carry Look AheadFile:Four bit ripple carry adder circuit diagram.png
4-bit adder with logic gates shownSome other multi-bit adder architectures break the adder into blocks. It is possible to vary the length of these blocks based on the propagation delay of the circuits to optimize computation time. These block based adders include the carry bypass adder which will determine P and G values for each block rather than each bit, and the carry select adder which pre-generates sum and carry values for either possible carry input to the block.
Other adder designs include the conditional sum adder, carry skip adder, and carry complete adder.
[edit] Lookahead Carry Unit
Main article: Lookahead Carry Unit
By combining multiple carry look-ahead adders even larger adders can be created. This can be used at multiple levels to make even larger adders. For example, the following adder is a 64-bit adder that uses four 16-bit CLAs with two levels of LCUs.
A 64-bit adder[edit] 3:2 compressors
We can view a full adder as a 3:2 compressor: it sums three one-bit inputs, and returns the result as a single two-bit number. Thus, for example, an input of 101 results in an output of 1+0+1=10 (2). The carry-out represents bit one of the result, while the sum represents bit zero. Likewise, a half adder can be used as a 2:2 compressor.
3:2 compressors can be used to speed up the summation of three or more addends. If the addends are exactly three, the layout is known as the carry-save adder. If the addends are four or more, more than one layer of compressors is necessary and there are various possible design for the circuit: the most common are Dadda and Wallace trees. This kind of circuit is most notably used in multipliers, which is why these circuits are also known as Dadda and Wallace multipliers.
A half adder is a logical circuit that performs an addition operation on two one-bit binary numbers often written as A and B. The half adder output is a sum of the two inputs usually represented with the signals Cout and S where . Following is the logic table for a half adder:
Inputs Outputs
A B C S
0 0 0 0
0 1 0 1
1 0 0 1
1 1 1 0
Example half adder circuit diagramAs an example, a Half Adder can be built with an XOR gate and an AND gate.
___________
A ------
Half
-----
Adder
-----
B ------
___________
[edit] Full adder
Schematic symbol for a 1-bit full adder with Cin and Cout drawn on sides of block to emphasize their use in a multi-bit adder.A full adder is a logical circuit that performs an addition operation on three one-bit binary numbers often written as A, B, and Cin. The full adder produces a two-bit output sum typically represented with the signals Cout and S where . The full adder's truth table is:
Inputs Outputs
A B Ci Co S
0 0 0 0 0
1 0 0 0 1
0 1 0 0 1
1 1 0 1 0
0 0 1 0 1
1 0 1 1 0
0 1 1 1 0
1 1 1 1 1
A full adder can be implemented in many different ways such as with a custom transistor-level circuit or composed of other gates. One example implementation is with and .
Example full adder circuit diagram
Inputs: {A, B, Cin} → Outputs: {S, Cout}File:Full Adder.JPG
Example full adder circuit diagram using only NAND and XOR gates
Inputs: {A, B, Cin} → Outputs: {S, Cout}In this implementation, the final OR gate before the carry-out output may be replaced by an XOR gate without altering the resulting logic. Using only two types of gates is convenient if the circuit is being implemented using simple IC chips which contain only one gate type per chip.
A full adder can be constructed from two half adders by connecting A and B to the input of one half adder, connecting the sum from that to an input to the second adder, connecting Ci to the other input and OR the two carry outputs. Equivalently, S could be made the three-bit XOR of A, B, and Ci, and Co could be made the three-bit majority function of A, B, and Ci.
[edit] Multiple-bit adders
[edit] Ripple carry adder
It is possible to create a logical circuit using multiple full adders to add N-bit numbers. Each full adder inputs a Cin, which is the Cout of the previous adder. This kind of adder is a ripple carry adder, since each carry bit "ripples" to the next full adder. Note that the first (and only the first) full adder may be replaced by a half adder.
The layout of ripple carry adder is simple, which allows for fast design time; however, the ripple carry adder is relatively slow, since each full adder must wait for the carry bit to be calculated from the previous full adder. The gate delay can easily be calculated by inspection of the full adder circuit. Each full adder requires three levels of logic. In a 32-bit [ripple carry] adder, there are 32 full adders, so the critical path (worst case) delay is 31 * 2(for carry propagation) + 3(for sum) = 65 gate delays.
[edit] Carry look-ahead adders
Main article: Carry look-ahead adder
To reduce the computation time, engineers devised faster ways to add two binary numbers by using carry lookahead adders. They work by creating two signals (P and G) for each bit position, based on whether a carry is propagated through from a less significant bit position (at least one input is a '1'), a carry is generated in that bit position (both inputs are '1'), or if a carry is killed in that bit position (both inputs are '0'). In most cases, P is simply the sum output of a half-adder and G is the carry output of the same adder. After P and G are generated the carries for every bit position are created. Some advanced carry look ahead architectures are the Manchester carry chain, Brent-Kung adder, and the Kogge-Stone adder.
4-bit adder with Carry Look AheadFile:Four bit ripple carry adder circuit diagram.png
4-bit adder with logic gates shownSome other multi-bit adder architectures break the adder into blocks. It is possible to vary the length of these blocks based on the propagation delay of the circuits to optimize computation time. These block based adders include the carry bypass adder which will determine P and G values for each block rather than each bit, and the carry select adder which pre-generates sum and carry values for either possible carry input to the block.
Other adder designs include the conditional sum adder, carry skip adder, and carry complete adder.
[edit] Lookahead Carry Unit
Main article: Lookahead Carry Unit
By combining multiple carry look-ahead adders even larger adders can be created. This can be used at multiple levels to make even larger adders. For example, the following adder is a 64-bit adder that uses four 16-bit CLAs with two levels of LCUs.
A 64-bit adder[edit] 3:2 compressors
We can view a full adder as a 3:2 compressor: it sums three one-bit inputs, and returns the result as a single two-bit number. Thus, for example, an input of 101 results in an output of 1+0+1=10 (2). The carry-out represents bit one of the result, while the sum represents bit zero. Likewise, a half adder can be used as a 2:2 compressor.
3:2 compressors can be used to speed up the summation of three or more addends. If the addends are exactly three, the layout is known as the carry-save adder. If the addends are four or more, more than one layer of compressors is necessary and there are various possible design for the circuit: the most common are Dadda and Wallace trees. This kind of circuit is most notably used in multipliers, which is why these circuits are also known as Dadda and Wallace multipliers.
No comments:
Post a Comment