Allicdata Part #: | 74ABT273APW,118-ND |
Manufacturer Part#: |
74ABT273APW,118 |
Price: | $ 0.00 |
Product Category: | Integrated Circuits (ICs) |
Manufacturer: | NXP USA Inc |
Short Description: | IC FF D-TYPE SNGL 8BIT 20TSSOP |
More Detail: | N/A |
DataSheet: | 74ABT273APW,118 Datasheet/PDF |
Quantity: | 1000 |
1 +: | 0.00000 |
Max Propagation Delay @ V, Max CL: | 4.6ns @ 5V, 50pF |
Base Part Number: | 74ABT273 |
Package / Case: | 20-TSSOP (0.173", 4.40mm Width) |
Mounting Type: | Surface Mount |
Operating Temperature: | -40°C ~ 85°C (TA) |
Input Capacitance: | 3.5pF |
Current - Quiescent (Iq): | 250µA |
Voltage - Supply: | 4.5 V ~ 5.5 V |
Current - Output High, Low: | 32mA, 64mA |
Trigger Type: | Positive Edge |
Series: | 74ABT |
Clock Frequency: | 350MHz |
Number of Bits per Element: | 8 |
Number of Elements: | 1 |
Output Type: | Non-Inverted |
Type: | D-Type |
Function: | Master Reset |
Part Status: | Obsolete |
Packaging: | Tape & Reel (TR) |
Due to market price fluctuations, if you need to purchase or consult the price. You can contact us or emial to us: sales@allicdata.com
Logic - Flip Flops are digital circuit components which are used for storing binary data. They are composed of four basic elements: a set of two stable states, a set of two flip-flops, a set of two clock inputs and a set of two outputs. Flip-flops are the main components in a digital circuit, they are normally used to store the state or data within a circuit, perform logical operations on it, or transfer data between different circuits. They are also used to transfer data between registers and between digital systems. The 74ABT273APW and 118 are two commonly used logic - flip-flops.
The 74ABT273APW logic - flip-flop is a 16-bit synchronous, mode-controlled, dual two-input latch. It has two input clock pins and two outputs, each of which can be used to store one binary bit. The data transfer direction is determined by the mode-control signal, and the 74ABT273APW can be used to transfer data from one register to another. It does this by capturing the lower order bit when the upper order bit is held in the previous register.
The 118 logic - flip-flop is a single edge-triggered flip-flop with a single clock input and two outputs. It can be used to store one bit of data and is used most commonly in a circuit as a ‘memory cell’ for storing the state of a register or a counter. It is activated when a logic HIGH is received on the clock input, which causes the output to toggle between LOW and HIGH. This logic - flip-flop is commonly used in synchronous digital systems since they are edge-triggered, meaning that data is transferred only when the clock edge is detected.
The main application of logic - flip-flops is in synchronous digital systems. They are used to store data and bits, perform logic operations, control communication between different parts of the system, and control the flow of data between different registers. They are also used in counter circuits and various types of memory systems. For example, logic - flip-flops are used in the Random Access Memory (RAM) for storing the register values, by utilizing the latching and shifting functions of the flip-flop.
The working principle of a logic - flip-flop is based on two stable states, usually referred to as SET and RESET. When one state is activated, the other state is prevented from being activated, allowing the circuit to retain its output state. When the input clock is triggered, the output of the flip-flop changes accordingly. When the clock is low, the output is set to the particular state, and when it is in the high state, the output changes to the opposite state. This behavior can be used to transfer data from one register to another, and it also allows for communication between digital systems.
In conclusion, the 74ABT273APW and 118 logic - flip-flops are commonly used digital circuit components which are used for storing binary data, controlling communication between parts of a system, and performing logical operations on it. They consist of four basic elements - two stable states, two flip-flops, two clock inputs and two outputs - and the working principle is based on the idea of two stable states and a triggered input clock that changes the output according to the state. This behavior allows for the transfer of data between two registers and also communication between two digital systems.
The specific data is subject to PDF, and the above content is for reference
Part Number | Manufacturer | Price | Quantity | Description |
---|
74ABT162244CSSC | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16541CMTD | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16543CSSC | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 5... |
74ABT16646CMTD | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 5... |
74ABT16952CMTD | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 5... |
74ABT245CMSA | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 2... |
74ABT245CMSAX | ON Semicondu... | -- | 1000 | IC TXRX NON-INVERT 5.5V 2... |
74ABT541CMSA | ON Semicondu... | 0.0 $ | 1000 | IC BUF NON-INVERT 5.5V 20... |
74ABT541CSJ | ON Semicondu... | 0.0 $ | 1000 | IC BUFFER NON-INVERT 5.5V... |
74ABT125CSJ | ON Semicondu... | 0.0 $ | 1000 | IC BUF NON-INVERT 5.5V 14... |
74ABT125CSJX | ON Semicondu... | 0.0 $ | 1000 | IC BUFFER NON-INVERT 5.5V... |
74ABT126CMTC | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 14... |
74ABT126CSJ | ON Semicondu... | 0.0 $ | 1000 | IC BUFFER NON-INVERT 5.5V... |
74ABT126CSJX | ON Semicondu... | 0.0 $ | 1000 | IC BUFFER NON-INVERT 5.5V... |
74ABT162244CMTD | ON Semicondu... | 0.0 $ | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT162244CSSX | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT162244MTDX | ON Semicondu... | 0.0 $ | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16244CMTD | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16244CMTDX | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16244CSSCX | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16245CMTD | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 4... |
74ABT16245CMTDX | ON Semicondu... | -- | 1000 | IC TXRX NON-INVERT 5.5V 4... |
74ABT16245CSSCX | ON Semicondu... | -- | 1000 | IC TXRX NON-INVERT 5.5V 4... |
74ABT16541CSSC | ON Semicondu... | 0.0 $ | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16541CSSCX | ON Semicondu... | -- | 1000 | IC BUF NON-INVERT 5.5V 48... |
74ABT16543CMTD | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 5... |
74ABT16543CSSCX | ON Semicondu... | -- | 1000 | IC TXRX NON-INVERT 5.5V 5... |
74ABT16646CSSC | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 5... |
74ABT16646CSSCX | ON Semicondu... | 0.0 $ | 1000 | IC TXRX NON-INVERT 5.5V 5... |
IC FF D-TYPE DUAL 8BIT 60HXQFN
IC FF D-TYPE SNGL 8BIT 20SOIC
IC FF D-TYPE SNGL 1BIT 8SOIC
IC FF D-TYPE SNGL 6BIT 16SOIC
IC FF D-TYPE SNGL 8BIT 20SOIC
IC FF D-TYPE SNGL 1BIT 8SOIC