Active filters amplify desired signals while rejecting unwanted frequencies, and can be tailored to meet application-specific requirements in electronics.
Amplifiers boost signal strength, match impedance levels, and are essential in many circuit systems, including audio, broadcasting, and telecommunications.
Batteries store and provide electrical energy, come in various types and sizes for multiple uses, rechargeable or single-use.
Capacitors store electrical charge with metallic plates and a dielectric; types vary and can be combined for specific circuit characteristics.
Chip carriers and sockets provide an interface between components and PCBs, enabling easy replacement or upgrading without soldering.
Circuit protection devices prevent damage from overcurrent flow, including fuses, breakers, surge protectors, and voltage regulators.
Connector accessories and support devices aid connector function and longevity, including backshells, grips, clamps, and ties; must be compatible with connector type.
Connectors join electronic circuits to transfer signals and power, come in various sizes and shapes, and include support accessories.
Converters transform DC input to another voltage level, essential in electronic systems, renewable energy, and automotive electronics.
Crystals and resonators generate and stabilize frequency signals via piezoelectricity. They are used in timing, frequency control, and filters. Crystals are quartz and resonators are ceramic with a built-in capacitor.
Semiconductor diodes control current flow in one direction (uni-directionality) via low resistance. Useful for rectification, voltage regulation, detection, and digital logic.
Discover essential electronic components for your devices, including CPU accelerators, system cache controllers, computer processors, motherboards, and graphics computing systems. Enhance device performance and connectivity with reliable components engineered for seamless integration and optimal functionality.
Fiber optics use light pulses to transmit data over long distances. They have superior bandwidth capacity, low signal attenuation, and secure physical properties. They are essential in telecommunications networks today.
Filters enhance signal processing by selectively passing desired frequencies while suppressing unwanted ones. Filters can be passive (using capacitors, resistors, and inductors) or active (using transistors or amplifiers).
Flash devices are non-volatile storage solutions that offer fast read and write speeds, making them ideal for applications requiring high-speed data transfer. These devices utilize flash memory technology, providing reliable storage for data-intensive tasks such as gaming, multimedia, and enterprise-level applications.
General purpose ICs consist of multiple individual circuits or components (e.g., logic gates, amplifiers, oscillators, etc.) that are combined onto a single integrated circuit chip for a smaller physical footprint.
I/O and storage controllers are crucial components in computer systems, managing input/output operations and storage devices. These controllers facilitate efficient data transfer between peripherals, storage drives, and the central processing unit (CPU), enhancing system performance and enabling seamless connectivity.
Inductors store energy in magnetic fields, oppose sudden changes in current flow and prevent electrical surges. Common inductor applications include power supplies, signal filters, and oscillators.
Interface ICs allow efficient device connectivity with high-speed data transfer and low power consumption.They can be ASIC or FPGA types, and may perform additional functions such as sensing, storage, and conversion.
Logic ICs can be used for storage, memory, amplification, and multiplexing. They perform fundamental logical operations on digital input signals (1, 0, H, L) to generate a corresponding digital output signal.
Memory modules are essential components in electronic devices, storing data temporarily or permanently for processing and retrieval. From volatile RAM (Random Access Memory) to non-volatile ROM (Read-Only Memory), memory technologies vary in speed, capacity, and functionality, catering to diverse application requirements.
Memory ICs store digital data and retain the information even when the power is turned off. They come in various types, like RAM (Random Access Memory) for fast data access, and ROM (Read-Only Memory) for permanent data storage.
Miscellaneous semiconductor components are a diverse category of electronic components that combines elements from a mix of component devices.
Optoelectronic devices interact with light. This family of devices can emit light, detect light, generate current, and transmit light signals for long-distance communication.
Oscillators generate repetitive waveforms, such as sine, square, or triangle waves. They are commonly used to produce stable and precise frequencies for applications like clocks, signal generation, and communication systems.
Other Function Semiconductor components are a diverse category of semiconductor components that perform a range of specialized functions.
Passive component networks operate without a power source and support data transmission within system by performing filtering, energy storage, and/or signal coupling functions.
Peripheral ICs (Integrated Circuits) are designed to control and manage the peripheral devices connected to a computer or other electronic device.
Programmable Logic ICs are user-programmable devices that allow designers to create custom logic circuits. These cost saving ICs offer real-time data processing and maximum design flexibilty.
RF (Radio Frequency) and microwave devices are used in telecommunications, wireless communications, and electronic systems. These devices include amplifiers, attenuators, filters, mixers, oscillators, and antennas, and a host of other components.
Voltage regulators are used to ensure a constant output voltage despite power fluctuations and load changes. Linear and switching regulators are common types used to maintain voltage stability.
Relays are electromagnetic switches that are used to control the flow of electrical current in an electrical circuit. Relays are a safe means of providing isolation between a controlling circuit and a controlled circuit.
Resistors control the flow of electrical current in a circuit by introducing a set resistance. These passive components reduce current flow, adjust signal levels, and bias active elements in circuits.
Transducers convert energy from one form to another and are crucial in sensing, audio and control systems. They transform physical measures like temperature, pressure, or sound into electrical signals for circuits.
Storage drives are hardware devices used to store and retrieve digital data in computers and electronic devices. These drives come in various forms, including hard disk drives (HDDs), solid-state drives (SSDs), and hybrid drives, offering different levels of capacity, speed, and durability to suit specific storage needs.
Storage media encompass physical or digital mediums used for storing and preserving digital data. From optical discs and magnetic tapes to USB flash drives and memory cards, storage media come in diverse formats and capacities, offering flexibility and reliability for data storage and archival purposes.
Storage systems comprise hardware and software components designed to manage and store digital data efficiently. These systems range from simple standalone devices to complex network-attached storage (NAS) and storage area network (SAN) solutions, providing scalable storage capacity and data protection features for businesses and enterprises.
Switches control electrical current flow by making or breaking connections. These devices vary in design and application, from basic on/off switches to complex industrial automation systems.
Telecom integrated circuits (ICs) are specialized electronics for telecommunications, tailored to high data rates, low power use, and reliable long-distance transmission. These devices include amplifiers, filters, ADCs, DACs, and more-- and they are often integrated on one chip for specific telecom tasks.
Terminal blocks, or connection terminals, are modular blocks that bring together multiple electrical wires at one connection point. They offer a reliable, organized way to terminate cables.
Thermal management devices control heat in electronic systems, preventing overheating and ensuring optimal performance and reliability. Examples include heat sinks, fans, and thermal interface materials that dissipate or transfer heat away from components.
Transformers are devices that alter electrical voltage levels between circuits through electromagnetic induction. They are vital in power distribution, converting high-voltage electricity for transmission and lower voltage for safe usage.
Transistors are 3-layer semiconductor devices that regulate the flow of electrical current. They function as amplifiers, boosting weak signals, and as switches, controlling the flow of current between terminals.
Triggering devices initiate electronic processes or events in response to specific conditions. These devices support many automated tasks such as activating switches and signals, or turning on lights when motion is detected.
Video cards, also known as graphics cards or GPU (Graphics Processing Unit), are essential components in computers, responsible for rendering graphics and images on display devices. These cards feature dedicated processors and memory, delivering smooth and immersive visual experiences for gaming, multimedia, and professional applications.
Choose from over than a million of proven quality materials. Over 300 manufacturers are presented. From renowned major international players to small independent companies with a proven track record in local markets.
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CDCLVD110AVF
Texas Instruments
CDCLVD110AVF clock driver by Texas Instruments features 3 ns propagation delay, 2.5V nominal voltage, and 10 true outputs at up to 1100 MHz. Ideal for industrial applications requiring differential mux input conditioning and a low profile flatpack package with a temperature range of -40 to 85°C.
110
DIFFERENTIAL MUX
S-PQFP-G32
e4
7 mm
5 pF
LOW SKEW CLOCK DRIVER
1
0
32
10
85 Cel
-40 Cel
3-STATE
PLASTIC/EPOXY
LQFP
QFP32,.35SQ,32
SQUARE
FLATPACK, LOW PROFILE
TRAY
260
2.5
160 mA
3 ns
Not Qualified
1.6 mm
Clock Driver
2.625 V
2.375 V
YES
INDUSTRIAL
NICKEL PALLADIUM GOLD
GULL WING
.8 mm
QUAD
30
1100 MHz
NB6L11MMNG
Onsemi
NB6L11MMNG by Onsemi is a clock driver with 0.325 ns propagation delay, suitable for industrial applications. It operates at a nominal voltage of 2.5V and supports differential input conditioning. This chip carrier package has 16 terminals and can withstand temperatures from -40 to 85°C.
NECL MODE: VCC = 0V WITH VEE = -2.375V TO -3.465V
6L
DIFFERENTIAL
S-XQCC-N16
3 mm
16
2
UNSPECIFIED
HVQCCN
LCC16,.12SQ,20
CHIP CARRIER, HEAT SINK/SLUG, VERY THIN PROFILE
+-2.5/+-3.3
.325 ns
.015 ns
1 mm
Clock Drivers
3.63 V
NICKEL GOLD PALLADIUM
NO LEAD
.5 mm
CDC351IDBG4
CDC351IDBG4 by Texas Instruments is a Clock Driver & Buffer with 4.2ns Propagation Delay, suitable for industrial applications. It operates at 3.3V with 24 terminals and offers 10 True Outputs at a max frequency of 100MHz. The package style is Small Outline, making it ideal for compact designs requiring precise timing control.
351
STANDARD
R-PDSO-G24
15.4 mm
50 pF
32 Amp
24
SOP
SSOP24,.3
RECTANGULAR
SMALL OUTLINE
TUBE
3.3
25 mA
4.2 ns
.9 ns
2.65 mm
3.6 V
3 V
BICMOS
Nickel/Palladium/Gold (Ni/Pd/Au)
1.27 mm
DUAL
NOT SPECIFIED
7.5 mm
100 MHz
CDC351IDWG4
Texas Instruments CDC351IDWG4 is Clock Driver & Buffer with 4.2ns Propagation Delay, 3.3V Supply Voltage, and 50pF Load Capacitance. Ideal for industrial applications due to -40 to 85°C operating temperature range and BICMOS technology. Package style: Small Outline, Surface Mountable with 24 terminals in Gull Wing form factor.
SOP24,.4
CDC351IDWRG4
CDC351IDWRG4 by Texas Instruments is a clock driver with 24 terminals and 3.3V nominal voltage. It features a propagation delay of 4.2ns, operates in industrial temperature range (-40 to 85°C), and has a max frequency of 100MHz. Ideal for applications requiring precise clock synchronization in electronic systems.
CDCLVD110AVFRG4
CDCLVD110AVFRG4 by Texas Instruments is a clock driver with 3 ns propagation delay, suitable for industrial applications. It operates at a nominal voltage of 2.5V and offers 10 true outputs with a max frequency of 100 MHz. This device features differential input conditioning and is designed for surface mount installation in a square package style.
TR
MAX9320BEUA-T
Maxim Integrated
LOW SKEW CLOCK DRIVER; Temperature Grade: INDUSTRIAL; Terminal Form: GULL WING; No. of Terminals: 8; Package Code: TSSOP; Package Shape: SQUARE;
ECL/LVECL MODE: VCC = 0 V WITH VEE = -3 V TO -5.5 V
S-PDSO-G8
e0
8
TSSOP
SMALL OUTLINE, THIN PROFILE, SHRINK PITCH
240
.265 ns
.03 ns
1.1 mm
5.5 V
5
Tin/Lead (Sn85Pb15)
.65 mm
20
3000 MHz
CDCL1810RGZRG4
LOW SKEW CLOCK DRIVER; Temperature Grade: INDUSTRIAL; Terminal Form: NO LEAD; No. of Terminals: 48; Package Code: HVQCCN; Package Shape: SQUARE;
1810
S-PQCC-N48
8 Amp
3
48
LCC48,.27SQ,20
1.8
.064 ns
1.9 V
1.7 V
650 MHz
CDCL1810RGZR
CDCL1810RGZR clock driver by Texas Instruments operates at 1.8V, with 48 terminals in a square package style. It offers 10 true outputs, a max operating temperature of 85°C, and supports differential input conditioning. Ideal for industrial applications requiring high-speed performance up to 650MHz.
CDCL1810RGZTG4
CDCL1810RGZTG4 clock driver by Texas Instruments operates at 1.8V, with 48 terminals and a max output of 8A. It features differential input conditioning, a temperature range of -40 to 85°C, and is ideal for industrial applications requiring a clock driver with a min frequency of 650MHz.
CDCL6010RGZRG4
CDCL6010RGZRG4 clock driver by Texas Instruments operates at 1.8V, with 48 terminals in a square package style. It features differential input conditioning, 10 true outputs up to 1250MHz, and a max operating temperature of 85°C. Ideal for industrial applications requiring precise clock signal distribution.
6010
PLL BASED CLOCK DRIVER
1250 MHz
CDCL6010RGZT
CDCL6010RGZT clock driver by Texas Instruments operates at 1.8V, with 48 terminals in a square package style. It features differential input conditioning, 10 true outputs up to 1250MHz, and a max operating temperature of 85°C. Ideal for industrial applications requiring precise clock signal distribution.
CDC328ADG4
Texas Instruments CDC328ADG4 is a Clock Driver with 5ns Propagation Delay, 16 Terminals, and 100MHz Min fmax. It operates at -40 to 85°C, suitable for industrial applications requiring precise clock signal distribution in compact designs.
COMBINATIONS OF TRUE AND COMPLEMENTARY OUTPUTS POSSIBLE WITH POLARITY-CONTROL INPUTS
328
R-PDSO-G16
9.9 mm
48 Amp
6
SOP16,.25
5 ns
1 ns
1.75 mm
5.25 V
4.75 V
3.9 mm
NB7L111MMNR2
NB7L111MMNR2 by Onsemi is a clock driver with 0.28 ns propagation delay at 2.5V, suitable for industrial applications. It features differential mux input conditioning, 52 terminals, and operates b/w -40 to 85 °C. Ideal for high-speed data transmission systems requiring precise timing control.
ALSO OPERATES WITH 3.3V SUPPLY
7L
S-XQCC-N52
8 mm
52
LCC52,.31SQ,20
235
2.5/3.3
.28 ns
.02 ns
TIN LEAD
NB7L111MMNR2G
NB7L111MMNR2G by Onsemi is a clock driver with 0.28 ns propagation delay at 2.5V, suitable for industrial applications. It features differential mux input conditioning and 10 true outputs, making it ideal for high-speed signal transmission in electronic systems. The chip carrier package style with a very thin profile and quad terminal position ensures efficient integration into compact designs.
e3
TIN
CDCVF855PWG4
Texas Instruments CDCVF855PWG4 is clock driver with 28 terminals, 3.5ns propagation delay, and 220MHz fmax. It operates at -40 to 85°C, has a load capacitance of 14pF, and supports differential input conditioning. Ideal for industrial applications requiring precise timing control in compact designs.
855
R-PDSO-G28
9.7 mm
14 pF
12 Amp
28
4
TSSOP28,.25
10 mA
3.5 ns
.04 ns
1.2 mm
2.7 V
2.3 V
4.4 mm
220 MHz
CDCVF855PWRG4
CDCVF855PWRG4 clock driver by Texas Instruments operates at 2.5V with 28 terminals and a load capacitance of 14pF. It features a propagation delay of 3.5ns, output characteristics in 3-STATE, and is ideal for industrial applications requiring differential input conditioning and a peak reflow temperature of 260°C.
AD9516-1BCPZ-REEL7
Analog Devices
AD9516-1BCPZ-REEL7 by Analog Devices features 1.18 ns propagation delay, 3.3V nominal voltage, and 800 MHz min fmax. Ideal for clock drivers & buffers in industrial applications requiring differential mux input conditioning and open-drain output characteristics.
9516
S-XQCC-N64
9 mm
CLOCK DRIVER
1 Amp
64
OPEN-DRAIN
LCC64,.35SQ,20
2.6 ns
.675 ns
3.465 V
3.135 V
MATTE TIN
800 MHz
AD9516-1BCPZ
AD9516-1BCPZ by Analog Devices features 1.18 ns propagation delay, 3.3V nominal voltage, and 10 true outputs at up to 800 MHz. Ideal for clock distribution in industrial applications due to its differential mux input conditioning and open-drain output characteristics.
NB4L339MNR4G
NB4L339MNR4G clock driver by Onsemi features 5ns propagation delay, operates at 2.5/3.3V, and offers differential input conditioning. Ideal for industrial applications requiring high-speed signal synchronization in a compact square package with 32 terminals.
4L
S-XQCC-N32
5 mm
LCC32,.2SQ,20
.19 ns
700 MHz
NB7V33MMNG
NB7V33MMNG clock driver by Onsemi is a differential input buffer with 16 terminals and a supply voltage of 1.8V. It has a propagation delay of 0.7ns, operates in industrial temperatures (-40 to 85 °C), and supports up to 10GHz frequency. Ideal for high-speed applications requiring precise signal synchronization.
IT ALSO OPERATES AT 2.5V SUPPLY
7V
10000000000 Hz
1.8/2.5
115 mA
.7 ns
.05 ns
Prescaler/Multivibrators
1.71 V
85311AMILFT
Integrated Device Technology
85311AMILFT by Integrated Device Technology is a clock driver with a propagation delay of 2.1 ns at 2.5V, suitable for industrial applications. It features differential input conditioning, surface mount capability, and a small outline package style. With dual terminal position and matte tin finish, it operates b/w -40 to 85°C temperature range.
ALSO OERATES AT 3.3 V
85311
R-PDSO-G8
4.9 mm
SOP8,.25
2.1 ns
85408BGILFT
85408BGILFT clock driver by Integrated Device Technology features a propagation delay of 2.4 ns, differential input conditioning, and operates at a supply voltage of 3.3V. This device is ideal for applications requiring precise timing synchronization in industrial settings due to its small outline package style and wide operating temperature range from -40°C to 85°C.
85408
7.8 mm
TSSOP24,.25
2.4 ns
AD9516-0BCPZ-REEL7
AD9516-0BCPZ-REEL7 by Analog Devices features 1.18 ns propagation delay, 3.3V nominal voltage, and 10 true outputs. Ideal for clock drivers & buffers in industrial applications requiring differential mux input conditioning and a max operating temperature of 85°C.
2950 MHz
AD9516-0BCPZ
AD9516-0BCPZ clock driver by Analog Devices has a propagation delay of 1.18 ns and operates at 3.3V. With 10 true outputs and a min fmax of 2950 MHz, it is ideal for industrial applications requiring precise timing synchronization in compact spaces.
AD9516-2BCPZ
AD9516-2BCPZ clock driver by Analog Devices has 1.18 ns propagation delay, 3.3V supply voltage, and 10 true outputs. Ideal for applications requiring differential mux input conditioning, with a package style of chip carrier suitable for industrial temperature grades.
AD9516-3BCPZ
Analog Devices' AD9516-3BCPZ is a clock driver with 64 terminals, 10 true outputs, and 2.6 ns propagation delay. It operates at -40 to 85 °C and supports up to 2950 MHz frequency, making it ideal for industrial applications requiring precise timing control in a compact square package.
AD9516-4BCPZ-REEL7
Analog Devices' AD9516-4BCPZ-REEL7 clock driver offers 1.18ns propagation delay, 3.3V nominal voltage, and 10 true outputs at up to 2950MHz. Ideal for applications requiring precise timing control in industrial settings with a temperature range of -40 to 85 °C.
AD9516-4BCPZ
AD9516-4BCPZ clock driver by Analog Devices has 1.18 ns propagation delay, 3.3V supply voltage, and 2.6 ns propagation delay. Ideal for applications requiring differential mux input conditioning, with a package style of chip carrier and operating temperature range of -40 to 85°C.
NB100LVEP221MNG
NB100LVEP221MNG Clock Driver by Onsemi features 0.8ns propagation delay, 52 terminals, and operates at -40 to 85 °C. Ideal for industrial applications requiring ECL technology with differential mux input conditioning and a supply voltage range of 2.375V to 3.8V.
NECL MODE: VCC = 0V WITH VEE = -2.375V TO -3.8V
100LVE
-2.5/-3.3/2.5/3.3
.71 ns
3.8 V
ECL
NB100LVEP222MNG
NB100LVEP222MNG Clock Driver by Onsemi features 52 terminals, 1ns propagation delay, and operates at -40 to 85 °C. It is used for differential mux input conditioning in industrial applications.
168 mA
.06 ns
NB4L6254MNG
NB4L6254MNG clock driver by Onsemi features a propagation delay of 0.61 ns, operates at a nominal voltage of 2.5V, and offers 6 true outputs with a min frequency of 3000 MHz. Ideal for industrial applications requiring high-speed signal conditioning in compact spaces due to its small chip carrier package style and low power consumption.
S-PQCC-N32
.485 ns
BIPOLAR
NB6HQ14MMNHTBG
NB6HQ14MMNHTBG clock driver by Onsemi features a propagation delay of 0.275 ns, differential input conditioning, and operates at a nominal voltage of 2.5V. This chip carrier with a square package shape is ideal for industrial applications requiring precise timing synchronization in temperature-sensitive environments.
6N
1.8/2.5,2.5
.275 ns
.5 ns
NB6HQ14MMNTXG
NB6HQ14MMNTXG clock driver by Onsemi features a low propagation delay of 0.275 ns, suitable for industrial applications. With differential input conditioning and 2 true outputs, it operates at temperatures ranging from -40 to 85 °C. This surface-mount chip carrier has a compact size of 3x3 mm and requires a nominal voltage of 2.5V.
CDCLVP1204RGTR
CDCLVP1204RGTR by Texas Instruments is a clock driver with a propagation delay of 0.43 ns, suitable for industrial applications. It operates at a nominal voltage of 2.5 V and has 16 terminals in a square package shape. With an output frequency up to 2000 MHz, it offers open-emitter output characteristics and requires a min supply voltage of 2.375 V.
CDC
MUX
OPEN-EMITTER
HQCCN
CHIP CARRIER, HEAT SINK/SLUG
45 mA
.43 ns
2000 MHz
CDCLVP1204RGTT
CDCLVP1204RGTT by Texas Instruments is a clock driver with 0.43 ns propagation delay, 2.5V nominal voltage, and 16 terminals in a square package. It is used for MUX input conditioning applications, operates at -40 to 85 °C, and has a max frequency of 2000 MHz suitable for industrial temperature grade environments.
CDCLVP1102RGTT
CDCLVP1102RGTT clock driver by Texas Instruments features a propagation delay of 0.43 ns, operates at 2.5/3.3V, and has a terminal pitch of 0.5mm. Ideal for industrial applications requiring high-speed clock distribution in compact spaces with differential input conditioning and open-emitter output characteristics.
DUMMY VAL
S-PQCC-N16
33 mA
.01 ns
CDCLVP1216RGZR
CDCLVP1216RGZR by Texas Instruments is a clock driver with 0.55 ns propagation delay, 2.5V nominal voltage, and 16 true outputs. It is used in applications requiring high-speed signal conditioning and differential multiplexing, suitable for industrial temperature environments.
110 mA
.55 ns
NICKEL PALLADIUM GOLD SILVER
CDCLVP1216RGZT
CDCLVP1216RGZT clock driver by Texas Instruments features a propagation delay of 0.55 ns, operates at a nominal voltage of 2.5V, and offers 16 true outputs with a min frequency of 2000 MHz. Ideal for industrial applications requiring precise timing synchronization in compact spaces.
CDCLVP2102RGTR
CDCLVP2102RGTR clock driver by Texas Instruments features a propagation delay of 0.4 ns, operates at a nominal voltage of 2.5V, and offers differential input conditioning. This chip carrier with a very thin profile is suitable for industrial applications requiring high-speed performance up to 2000 MHz.
48 mA
.4 ns
CDCLVP2102RGTT
CDCLVP2102RGTT clock driver by Texas Instruments features a propagation delay of 0.4 ns, operates at a nominal voltage of 2.5V, and offers differential input conditioning. This chip carrier with a very thin profile is ideal for applications requiring high-speed clock distribution in industrial settings.
CDCLVP2108RGZR
CDCLVP2108RGZR clock driver by Texas Instruments features a propagation delay of 0.55 ns, operates at a nominal voltage of 2.5V, and offers 16 true outputs. Ideal for industrial applications requiring high-speed clock distribution with differential input conditioning in a compact chip carrier package style.
.025 ns
SN65EPT21DGKR
SN65EPT21DGKR clock driver by Texas Instruments features a propagation delay of 1.9 ns, differential input conditioning, and operates at a max frequency of 300 MHz. Ideal for industrial applications requiring precise timing control in systems with load capacitance up to 20 pF.
65EP
20 pF
24 Amp
1.9 ns
.25 ns
300 MHz
SN65EPT21D
SN65EPT21D clock driver by Texas Instruments features a 1.9 ns propagation delay, 3.3V nominal voltage, and 300 MHz min fmax. Ideal for industrial applications requiring differential input conditioning, this ECL technology device comes in a small outline package with surface mount capability.
NB6L572MMNG
NB6L572MMNG clock driver by Onsemi features a propagation delay of 10ns, operates at 2.5V, and has a terminal pitch of 0.5mm. It is used in applications requiring differential mux input conditioning and offers a max operating temperature of 85°C.
ALSO OPERATES AT 3.3 V
5000 MHz
NB6L572MMNR4G
NB6L572MMNR4G clock driver by Onsemi has a propagation delay of 10ns, operates at 2.5V, and offers differential mux input conditioning. It is ideal for applications requiring precise timing control in industrial settings due to its high frequency capabilities up to 5000MHz.
NB6LQ572MMNG
NB6LQ572MMNG clock driver by Onsemi features a 10 ns propagation delay at 2.5V, suitable for industrial applications. With differential mux input conditioning and 32 terminals in a square package, it offers 2 true outputs and operates up to 5000 MHz, making it ideal for high-speed signal processing.
NB7L585RMNG
NB7L585RMNG clock driver by Onsemi features a propagation delay of 0.3ns, differential mux input conditioning, and 6 true outputs with a min fmax of 6000MHz. Ideal for applications requiring precise clock signal distribution in industrial settings due to its low delay and high-speed capabilities.
.225 ns
6000 MHz
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