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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and cant generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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Resistors are electronic components which have a specific, never-changing electrical resistance. The resistor’s resistance limits the flow of electrons through a circuit. They are passive components, meaning they only consume power (and can’t generate it). Resistors are usually added to circuits where they complement active components like op-amps, microcontrollers, and other integrated circuits. Commonly resistors are used to limit current, divide voltages, and pull-up I/O lines.
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-8%
This Tri-state bi-directional transceiver utilize advanced silicon-gate CMOS technology and is intended for two-way asynchronous communication between data buses. They have high drive current outputs which enable high speed operation even when driving large bus capacitances. The circuit possess the low power consumption of CMOS circuitry, yet have speeds comparable to low power Schottky TTL circuits.
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-9%
- Internally frequency compensated for unity gain
- Large DC voltage gain 100 dB
- Wide bandwidth (unity gain) 1 MHz (temperature compensated)
- Very low supply current drain (700 A) essentially independent of supply voltage
- Low input biasing current 45 nA (temperature compensated)
- Low input offset voltage 2 mV and offset current: 5 nA
- Input common-mode voltage range includes ground
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-19%
Out Of StockThe AD7528 is a monolithic dual 8-bit digital/analog converter featuring excellent DAC-to-DAC matching. It is available in skinny 0.3″ wide 20-lead DIPs and in 20-lead surface mount packages. Separate on-chip latches are provided for each DAC to allow easy microprocessor interface.
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-26%
SIP Resistor Arrays (Single Inline Package) is an efficient way to pack several of the same value resistors into a convenient 0.1 spaced package. Available in different resistance values and number of pins. Pin 1 is identified with a dot above the pin also known as Resistor Networks.
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-21%
Out Of Stock- HP2730 Opto Coupler IC
- Number of Channels: 2
- Voltage – Isolation: 2500 Vrms
- Current Transfer Ratio (Min): 300% @ 1.6 mA
- Turn On / Turn Off Time (Typ): 300 ns, 5 s
- Input Type: DC
- Output Type: Darlington
- Voltage – Output (Max): 7 V
- Current – Output / Channel: 60 mA
- Voltage – Forward (Vf) (Typ): 1.3 V
- Current – DC Forward (If) (Max): 20 mA
- Operating Temperature: -40C to 85C
- Mounting Type: Through Hole
- Package: 8-DIP (0.300″, 7.62mm)
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Specifications:
- Power (Watts) 1W
- Resistant 22K OHMS
- Tolerance +- 5%
- Resistor Type Carbon Film
- Lead Free
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The CD4050 hex buffers are monolithic complementary MOS (CMOS) integrated circuits constructed with N- and P-channel enhancement mode transistors. These devices feature logic level conversion using only one supply voltage (VDD). The input signal high level (VIH) can exceed the VDD supply voltage when these devices are used for logic level conversions. These devices are intended for use as hex buffers, CMOS to DTL/ TTL converters, or as CMOS current drivers, and at VDD = 5.0V, they can drive directly two DTL/TTL loads over the full operating temperature range.
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- Inverting IC that can convert High logic level to Low level
- High source and Sink Current as it has the capability of driving 2 TTL Loads at 5V over full temperature range.
- 100% Tested for Quiescent Current at 20 V
- Maximum Input Current of 1A at 18 V Over Full Package Temperature Range; 100 nA at 18 V and 25C
- 5-V, 10-V, and 15-V Parametric Ratings
- It is available in 16 pin packages of PDIP, SOIC, TSSOP, SO.
- Special input protection to protect inputs against static discharges.
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- Wide supply voltage range: 3V to 15V
- Low power: 100 nW (typ.)
- High noise immunity: 0.45 VDD (typ.)
- Separate SET and RESET inputs for each latch
- NOR and NAND configuration
- 3-STATE output with common output enable
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The CD4024 is a 7-stage ripple-carry binary counter. Buffered outputs are externally available from stages 1 through 7. The counter is reset to its logical 0 stage by a logical 1 on the reset input. The counter is advanced one count on the negative transition of each clock pulse.
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- Asynchronous Set-Reset Capability
- Static Flip-Flop Operation
- Medium-Speed Operation: 16 MHz (Typical) Clock Toggle Rate at 10-V Supply
- Standardized Symmetrical Output Characteristics
- Maximum Input Current Of 1- A at 18 V Over Full Package Temperature Range:
- 100 nA at 18 V and 25C
- Noise Margin (Over Full Package Temperature Range):
- 1 V at VDD = 5 V
- 2 V at VDD = 10 V
- 2.5 V at VDD = 15 V
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- Wide supply voltage range 3.0V to 15V
- Low power 10 nW (typ.)
- High noise immunity 0.45 VDD (typ.)
- Buffered Inputs and Outputs
- Standard Symmetrical Output Characteristics
- 100% Tested for Maximum Quiescent Current at 20V
- 5V, 10V and 15V Parametric Ratings
- Maximum Input Current of 1A at 18V Over Full Package-Temperature Range; 100nA at 18V and +25oC
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- High Voltage Type (20V Rating)
- 3-State Parallel Outputs for Connection to Common Bus
- Separate Serial Outputs Synchronous to Both Positive and Negative Clock Edges for Cascading
- Medium Speed Operation – 5MHz at 10V (typ)
- Quiescent Current at 20V
- Maximum Input Current of 1A at 18V Over Full Package Temperature Range; 100nA at 18V and +25oC
- Noise Margin (Over Full Package/Temperature Range) – 1V at VDD = 5V – 2V at VDD = 10V – 2.5V at VDD = 15V
- 5V, 10V and 15V Parametric Ratings
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- Dual inputQuad NAND gate operation.
- Input voltage range: -0.5 to VDD +5V
- Power dissipation of 100mW per logic change.
- It is available in different outline packages
- The propagation delay time is 60ns
- All input and output pins are buffered for high throughput
- The output characteristics are standardized symmetric
- CD4011 draws a maximum input current of 1 Ampere at 18 volts
- Offers different noise margin level according to the input voltage level
- Temperature operating range is -55C to +125C
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The CD4081 quad gate is a monolithic complementary MOS (CMOS) integrated circuit constructed with N- and P-channel enhancement mode transistors. They have equal source and sink current capabilities and conform to standard B series output drive. The devices also have buffered outputs which improve transfer characteristics by providing very high gain. All inputs protected against static discharge with diodes to VDD and VSS.
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- Operating Voltage: 5V, 10V, 15V DC
- Maximum Input Current: 1uA
- Hysteresis Voltage Typically 0.9 V at VDD: 5 V and 2.3 V at VDD: 10 V
- Noise Immunity Greater Than 50%
- Unlimited input rise and fall times
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The 4077 is a quad 2-input EXCLUSIVE-NOR gate. The outputs are fully buffered for the highest noise immunity and pattern insensitivity to output impedance. The 4077 operates over a recommended VDD power supply range of 3 V to 15 V referenced to VSS (usually ground). Unused inputs must be connected to VDD, VSS, or another input.
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- High Speed Binary Ripple Carry Counter
- Separate Reset Input Pin
- Wide Operating Voltage Range: 2.0 to 6.0 V
- Output Drive up to 10 LS-TTL Loads
- Equivalent to CD4060
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- High-Voltage Types (20V Rating)
- CD4071BMS Quad 2-Input OR Gate
- CD4072BMS Dual 4-Input OR Gate
- CD4075BMS Triple 3-Input OR Gate
- Medium Speed Operation: tPHL, tPLH = 60ns (typ) at 10V
- 100% Tested for Quiescent Current at 20V
- Maximum Input Current of 1A at 18V Over Full Package Temperature Range; 100nA at 18V and +25oC
- Standardized Symmetrical Output Characteristics
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- Supply voltage ranges from 3v to 18v
- Set-up-time is 150, 70, and 40ns at 5v, 10v, and 15v respectively
- Strobe pulse width is 400, 160, and 100ns at 5v, 10v, and 15v respectively
- Hold time is zero
- 100% tested for quiescent current at 20v
- Having high input current of 1uA (max.) at 18v
- Maximum output current sourcing of 25mA
- Operating temperature ranges from -40 C to 85 C
- Storage temperature ranges from -65 C to 150 C
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-40%
IC sockets are generally for preventing damage to IC’s from soldering and while testing multiple circuits. These are made from Black Thermoplastic and tin-plated alloy contacts. One end is notched to aid in identification. They can be mounted end to end to suit longer IC’s.
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-18%
This is a IC Socket/Base for 28 pin SMD PLCC IC. This is a SMT base and is advisable on boards with point to point wiring because replacing a defective IC is time consuming and can possibly damage your prototype board. The use of an IC socket is inexpensive compared to the time and effort required to replace an IC chip. IC sockets also reduce the possibility of damaging the board when swapping out IC’s.
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IC sockets are generally for preventing damage to IC’s from soldering and while testing multiple circuits. These are made from Black Thermoplastic and tin-plated alloy contacts. One end is notched to aid in identification. They can be mounted end to end to suit longer IC’s.
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14 Pin – DIP IC Socket/Base IC sockets are generally for preventing damage to IC’s from soldering and while testing multiple circuits. These are made from Black Thermoplastic and tin-plated alloy contacts. One end is notched to aid in identification. They can be mounted end to end to suit longer IC’s.
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Features and Technical Specification
- Having a high value of current (max. 600 mA)
- Low voltage value (max. 40 V)
- It comes in different types of packages TO-92, TO-18
- These are Lead (Pb) free devices
- Collector to Emitter voltage (VCEO) is 40v (max.)
- Collector to Base voltage (VCBO) is 60v (max.)
- Emitter to Base voltage(VEBO) is 5v (normally)
- The maximum value of Collector current is 600mA
- Power dissipation at ambient temperature is about 400mW
- Having DC current gain (hfe) of 100 to 300 (max.)
- The temperature of operation and storage is -65 to +150 C
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- Bi-Polar PNP Transistor
- DC Current Gain (hFE) is 300 maximum
- Continuous Collector current (IC) is 200mA
- Emitter Base Voltage (VBE) is 5V
- Base Current(IB) is 5mA maximum
- Collector Emitter Voltage (VCE) is 40V
- Collector Base Voltage (VCB) is 40V
- Available in To-92 Package
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-15%
- Small Signal NPN Transistor
- Current Gain (hFE), typically 50 for small signal
- Continuous Collector current (IC) is 800mA
- Collector-Emitter voltage (VCEO) is 50 V
- Collector-Base voltage (VCB0) is 75V
- Emitter Base Voltage (VBE0) is 6V
- Turn on time is 40ns
- Turn off time is 250ns
- Available in To-92 Package
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-14%
- N-Channel Power MOSFET
- Continuous Drain Current (ID) is 110A when VGS is 10V
- Minimum Gate threshold voltage 2V
- Drain to Source Breakdown Voltage: 55V
- Low On-Resistance of 8.0m
- Gate-Source Voltage is (VGS) is 20V
- Rise time is 101ns
- It is commonly used with Power Switching circuits
- Available in To-220 package
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- Fast Switching Applications
- Uninterruptible Power Supplies
- Battery Chargers
- Battery Management Systems
- Solar Battery Chargers
- Solar Uninterruptible Power Supplies
- Motor Driver Applications
- Telecommunication Applications
- Computer Related Applications
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-15%
IRFP250 N-channel Power MOSFET
Original price was: ₨280.00.₨239.00Current price is: ₨239.00. Quick View- Repetitive Avalanche Ratings
- Dynamic dv/dt Rating
- Hermetically Sealed
- Simple Drive Requirements
- Ease of Paralleling
- Type Designator: IRF250
- Type of Transistor: MOSFET
- Type of Control Channel: N -Channel
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- Package Type: TO-220
- Transistor Type: N Channel
- Max Voltage Applied From Drain to Source: 55V
- Max Gate to Source Voltage Should Be: 20V
- Max Continues Drain Current is : 49A
- Max Pulsed Drain Current is: 160A
- Max Power Dissipation is: 94W
- Minimum Voltage Required to Conduct: 2V to 4V
- Max Storage & Operating temperature Should Be: -55 to +170 Centigrade
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- Low saturation voltage
- Simple drive requirements
- High safe operating area
- For low distortion complementary designs
- Easy to carry and handle
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The Bipolar Power Transistor is designed for use in general purpose amplifier and switching applications.
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TIP122 transistor designed for general purpose amplifier and low speed switching applications.
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- Type –NPN
- Collector-Emitter Voltage: 60V
- Collector-Base Voltage: 60V
- Emitter-Base Voltage: 5V
- Collector Current: 3A
- Collector Dissipation – 30W
- DC Current Gain (hfe) –40 to 320
- Transition Frequency – 5 MHz
- Operating and Storage Junction Temperature Range -55 to +150C
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-46%
- Type Designator: 2SC2331
- Material of transistor: Si
- Polarity: NPN
- Maximum collector power dissipation (Pc), W: 1
- Maximum collector-base voltage |Ucb|, V: 80
- Maximum collector-emitter voltage |Uce|, V: 60
- Maximum emitter-base voltage |Ueb|, V: 8
- Maximum collector current |Ic max|, A: 0.7
- Transition frequency (ft), MHz: 30
- Collector capacitance (Cc), pF: 8
- Forward current transfer ratio (hFE), min: 40
- Noise Figure, dB: –
- Package of 2SC2331 transistor: TO92
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C1383 is a Bipolar NPN type transistor which is used for low-frequency power amplification and driver amplification.
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- 2sc925 well known as C945 NPN transistor.
- Max Voltage Collector Emmiter=50 V.
- Max Collector current=150 mA.
- Collector power dissipation: 400 mW.
- Japanese High-frequency amplifier NPN Transistor.
- Current Gain (hFE) is 70 to 700 (high linearity).
- Continuous Collector current (IC) is 150mA.
- Collector-Emitter voltage (VCEO) is 50 V.
- Collector-Base voltage (VCB0) is 60V.
- Emitter Base Voltage (VBE0) is 5V.
- Transition Frequency is 150MHz.
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- Type – NPN
- Collector-Emitter Voltage: 25 V
- Collector-Base Voltage: 30 V
- Emitter-Base Voltage: 7 V
- Collector Current: 0.05 A
- Collector Dissipation – 0.4 W
- DC Current Gain (hfe) – 130 to 520
- Transition Frequency – 220 MHz
- Noise Figure – 6 dB
- Operating and Storage Junction Temperature Range -55 to +150 °C
- Package – TO-92