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Price & Stock for: TLC555IDR

Distributor Stock MOQ Package QTY Break / Prices
View this part on Newark 0 2,500 TAPE & REEL FULL
  • 2,500 $0.8450
View this part on Newark 0 1 TAPE & REEL CUT
  • 1 $1.4900
  • 10 $1.3900
  • 25 $1.3000
  • 50 $1.2200
View this part on Bristol Electronics 2,249 1
View this part on Bristol Electronics 7 3
  • 3 $1.8750
View this part on Bristol Electronics 334 1

Purchasing Insights: TLC555IDR

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Risk Rank

Risk Rank is a proprietary algorithm Supplyframe has developed to quantify component risk rank using multiple data points. This ranking helps engineers and buyers determine whether alternates should be sought for parts that are deemed as high risk.

Risk Rank Example

Risk Rank is determined by a combination of factors such as product lifecycle status, price & inventory votality, current inventory availability, and much more. Even the availability of manufacturer specifications and part documentation, such as datasheets and reference designs, have an impact on determining the overall riskiness of a part.

The risk is characterized across three product phases:

  • Design
  • Production
  • Long Term

For Purchasing Risk Rank, we focus on the Production and the Long Term Phases on FindChips in our evaluation of Risk.

Production Phase

The production phase is when the product is being assembled. Sourcing parts reliably is the essential task during this phase, as it determines whether the product can continue production. During the production phase, there is no time to test new components if something goes awry – the design is the locked-in and a primary risk factor is the component availability in the marketplace. It is possible to utilize alternative parts if things go wrong during this phase, but they need to be FFF (form, fit, function) compatible. Therefore, if a part is available in the online marketplace and has available FFF components, it will be listed as lower risk.

Long Term Phase

The amount of time that a product is manufactured often depends on the industry. Some automobile electronics are made consistently for 5-10 years, whereas military and industrial electronics could be produced from anywhere from 30-50 years.

This means part risk goes up with the likelihood of obsolescence. If a chip manufacturer decides to stop making a particular chip, it is supremely disruptive to mature products, because there may not even be replacement parts available. Other factors like environmental certifications (RoHS) feed into this as well, as non-certified parts are more likely to become obsolete in the future.

We combine both of these aspects into a Purchasing Risk Rank score in order to focus in on risk elements that would be most pertinent for purchasers to be aware of.

Risk Rank Breakdown

Risk Rank: Purchasing Risk

What is purchasing risk rank?

Purchasing Risk Rank is determined by in-depth analysis across risk factors of production risk and long term risk of a given part.

Learn more

Market Price Analysis

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Part Details for: TLC555IDR

CAD Models

Part Details

Risk Rank

Risk Rank is a proprietary algorithm Supplyframe has developed to quantify component risk rank using multiple data points. This ranking helps engineers and buyers determine whether alternates should be sought for parts that are deemed as high risk.

Risk Rank Example

Risk Rank is determined by a combination of factors such as product lifecycle status, price, inventory votality, current inventory availability, and much more. Even the availability of manufacturer specifications and part documentation, such as datasheets and reference designs, have an impact on determining the overall riskiness of a part.

The risk is characterized across three product phases:

  • Design
  • Production
  • Long Term

We focus on the Design Phase on FindChips in our evaluation of Risk.

Design Phase

The design phase of a product is the beginning of the product lifecycle. This is when engineers are doing analysis of components in the marketplace, determining which specifications are most important for their design and assessing the cost impact of using this particular component. While this is early in the product lifecycle, choices at this point can severely impact a product much later on when the product is being made. Additionally, this stage is the one furthest from a product being made, which is why we focus on metrics of stability over time when determining Design Risk.

Risk Rank Breakdown

Risk Rank: Design Risk

What is design risk rank?

Design Risk Rank is determined by in-depth analysis across risk factors, including part availability, functional equivalents, lifecycle, and more.

Learn more

Alternate Parts for: TLC555IDR

Part Number Description Manufacturer Compare
SE555DRG4 Signal Circuits Precision timer for -55 to 125C operation 8-SOIC -55 to 125 Texas Instruments TLC555IDR vs SE555DRG4
933975630602 Signal Circuits IC PULSE, 0.5 MHz, TIMER, PDSO8, PLASTIC, SOT-96, SO-8, Analog Waveform Generation Function NXP Semiconductors TLC555IDR vs 933975630602
935290988118 Signal Circuits PULSE, 0.5MHz, TIMER, PDSO8, 3.90 MM, PLASTIC, MS-012, SOT96-1, SOP-8 NXP Semiconductors TLC555IDR vs 935290988118
MC1455BDR2 Signal Circuits PULSE, TIMER, PDSO8, PLASTIC, SO-8 Motorola Mobility LLC TLC555IDR vs MC1455BDR2
SA555D Signal Circuits Analog Waveform Generation Function, BIPolar, Philips Semiconductors TLC555IDR vs SA555D
ICM7555CD/01,112 Signal Circuits ICM7555CDSOT96-1 NXP Semiconductors TLC555IDR vs ICM7555CD/01,112
TLC555CDRG4 Signal Circuits 2.1-MHz, 250-µA, Low-Power Timer 8-SOIC 0 to 70 Texas Instruments TLC555IDR vs TLC555CDRG4
Part Number Description Manufacturer Compare
MC1455BDR2 Signal Circuits PULSE, TIMER, PDSO8, PLASTIC, SO-8 Motorola Mobility LLC TLC555IDR vs MC1455BDR2
935290988118 Signal Circuits PULSE, 0.5MHz, TIMER, PDSO8, 3.90 MM, PLASTIC, MS-012, SOT96-1, SOP-8 NXP Semiconductors TLC555IDR vs 935290988118
933975630602 Signal Circuits IC PULSE, 0.5 MHz, TIMER, PDSO8, PLASTIC, SOT-96, SO-8, Analog Waveform Generation Function NXP Semiconductors TLC555IDR vs 933975630602
CA0555M96 Signal Circuits 1 Func, PDSO8 Rochester Electronics LLC TLC555IDR vs CA0555M96
SE555DRG4 Signal Circuits Precision timer for -55 to 125C operation 8-SOIC -55 to 125 Texas Instruments TLC555IDR vs SE555DRG4
TLC555CDRG4 Signal Circuits 2.1-MHz, 250-µA, Low-Power Timer 8-SOIC 0 to 70 Texas Instruments TLC555IDR vs TLC555CDRG4
ICM7555CBA Signal Circuits SQUARE, 1MHz, TIMER, PDSO8, PLASTIC, SOIC-8 Intersil Corporation TLC555IDR vs ICM7555CBA
SA555D Signal Circuits Analog Waveform Generation Function, BIPolar, Philips Semiconductors TLC555IDR vs SA555D
ICM7555CBA-T Signal Circuits ICM7555CBA-T Intersil Corporation TLC555IDR vs ICM7555CBA-T
ICM7555CD/01,112 Signal Circuits ICM7555CDSOT96-1 NXP Semiconductors TLC555IDR vs ICM7555CD/01,112

Resources and Additional Insights

Reference Designs

  • Sync Buck for Intel Atom E6xx Tunnel Creek (1.1V @ 3.5A)
    PMP5922.1: TI's Highest Power Density Low Input Voltage Complete Intel Atom E6xx (Tunnel Creek) power system designs; in 967mm2 this design has all the voltage regulators needed to power Intel's Atom E6xx CPU platform and fit onto a 70x70 or smaller COM Express Module used in Industrial Automation and Process Control applications.
  • PMP20490 High-Density 12Vin, 1.2Vout, 60A POL Reference Design with Stacked TPS546C20A PMBus DCDC Converters | TI.com
    PMP20490: The TPS546C23 provides a single IC for both control & the synchronous power stage for high current DC/DC applications and allows doubling of the current capability with use of two of the same part. Multi-phase also allows output ripple cancellation and effective higher bandwidth control for a given switching frequency. PMP20490 shows a high current two phase application with inductors on top of control ICs for smaller footprint and two on board dynamic loads. The test report shows performance and efficiency with two sources of inductors.
  • 5V, 3-Phase, Sensorless, Sinusoidal Motor System With Variable Speed Control
    TIDA-00114: This BLDC motor system implements a DRV10963, a TLC555 timer, and a generic 5V motor. The sinusoidal control scheme is suitable for small fan applications where low noise is desired. Motor voltage support is 2.1V to 5.5V, and max current is 500mA. Motor speed is controlled by the PWM input. Low quiescent current standby mode is available. The motor drive stage has integrated protection, including short-circuit, shoot-through, under-voltage, over-temperature, and locked rotor detection.
  • PMP2688 Power Solution for Automotive Audio Amplifiers | TI.com
    PMP2688: This reference design supports the supply for an audio amplifier, such as the TAS5414C-Q1 using the various DC/DC power switchers, LDOs, logic, clocks, and op amps. This reference design is also applicable in start/stop systems. Modifying this reference design can also create a power supply for a radio head unit.
  • Power Solution for Automotive Audio Amplifiers
    PMP2688: This reference design supports the supply for an audio amplifier, such as the TAS5414C-Q1 using the various DC/DC power switchers, LDOs, logic, clocks, and op amps. This reference design is also applicable in start/stop systems. Modifying this reference design can also create a power supply for a radio head unit.
  • TIDA-00114 5V, 3-Phase, Sensorless, Sinusoidal Motor System With Variable Speed Control | TI.com
    TIDA-00114: This BLDC motor system implements a DRV10963, a TLC555 timer, and a generic 5V motor. The sinusoidal control scheme is suitable for small fan applications where low noise is desired. Motor voltage support is 2.1V to 5.5V, and max current is 500mA. Motor speed is controlled by the PWM input. Low quiescent current standby mode is available. The motor drive stage has integrated protection, including short-circuit, shoot-through, under-voltage, over-temperature, and locked rotor detection.
  • TIDA-00112 5V, 3-Phase, Sensorless Motor System With Variable Speed Control | TI.com
    TIDA-00112: This reference design provides a simple way to spin and control a 5V, 3-phase, BLDC fan motor with minimum development time and overhead. It utilizes the DRV10866, a sensorless BLDC motor driver, for the power stage and a TLC555 timer to provide a variable duty cycle PWM signal for speed control. The DRV10866 uses a 150 degree sensorless BEMF control scheme that takes away the need for external sensors on the motor.
  • PMP5922 Sync Buck for Intel Atom E6xx Tunnel Creek (1.25V @ 10mA) | TI.com
    PMP5922: TI's Highest Power Density Low Input Voltage Complete Intel Atom E6xx (Tunnel Creek) power system designs; in 967mm2 this design has all the voltage regulators needed to power Intel's Atom E6xx CPU platform and fit onto a 70x70 or smaller COM Express Module used in Industrial Automation and Process Control applications.
  • PMP5922 Sync Buck for Intel Atom E6xx Tunnel Creek (1.25V @ 10mA) | TI.com
    PMP5922: TI's Highest Power Density Low Input Voltage Complete Intel Atom E6xx (Tunnel Creek) power system designs; in 967mm2 this design has all the voltage regulators needed to power Intel's Atom E6xx CPU platform and fit onto a 70x70 or smaller COM Express Module used in Industrial Automation and Process Control applications.
  • Double Boost TPS40210
  • 5V, 3-Phase, Sensorless Motor System With Variable Speed Control
    TIDA-00112: This reference design provides a simple way to spin and control a 5V, 3-phase, BLDC fan motor with minimum development time and overhead. It utilizes the DRV10866, a sensorless BLDC motor driver, for the power stage and a TLC555 timer to provide a variable duty cycle PWM signal for speed control. The DRV10866 uses a 150 degree sensorless BEMF control scheme that takes away the need for external sensors on the motor.
  • PMP2663 Double Boost TPS40210 | TI.com

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