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GRM1555C1H220JA01D by:
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Price & Stock for: GRM1555C1H220JA01D

Distributor Stock MOQ Package QTY Break / Prices
View this part on Avnet Americas 480,000 10,000 Reel
  • 10,000 $0.0045
  • 20,000 $0.0043
  • 40,000 $0.0042
  • 60,000 $0.0041
  • 80,000 $0.0039
  • 100,000 $0.0035
  • 1,000,000 $0.0034
View this part on Newark 0 10 TAPE & REEL CUT
  • 10 $0.0420
  • 25 $0.0280
  • 50 $0.0190
  • 100 $0.0150
  • 250 $0.0120
  • 500 $0.0100
  • 1,000 $0.0080
View this part on Bristol Electronics 59,310 112
  • 112 $0.0450
  • 335 $0.0300
  • 1,168 $0.0075
  • 10,001 $0.0045
  • 27,779 $0.0038
  • 52,633 $0.0036
View this part on Bristol Electronics 20,000 1
View this part on Bristol Electronics 159,706 1

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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.

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Part Details for: GRM1555C1H220JA01D

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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

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.

Resources and Additional Insights

Reference Designs

  • Automotive ADAS Power Design Optimized for Xilinx® Zynq® 7010 SoC
    TIDA-00389: The TIDA-00389 design is an optimized power solution for Xilinx® Zynq® 7010 FPGA/SoC (out of the Zynq® 7000 series family of products). It targets ADAS applications where customers opt to use FPGA instead of Multicore DSP or MPU. This design runs from a single intermediate 3.3V or 5V power supply rail and provides a complete solution to power the Xilinx® Zynq® 7010. DDR memory termination and a 5V supply for a CAN Transceiver are also implemented. A LM3880 provides power up and power down sequencing. The design is tested and optimized for automotive applications.
  • 85 to 265VAC Input 5V@4A Dual Port Charger For Tablets and Smart Phones Reference Design
    PMP8817: This reference design is capable of charging two devices at 2A each with over 85% efficiency. The UCC24610 synchronous rectifier controller and CSD18533Q5A FET reduce the rectifier loss and provide ultra-high efficiency with a minimal increase in cost. The UCC28700 primary-side regulated flyback further minimizes cost by eliminating the need for an opto-coupler, and yet maintains good output regulation. The TPS2561A provides accurate and independent current limit protection for each port. The TPS2513 communicates with the mobile device under charge to ensure that the charger is accepted by most phone and tablet models. This compact design consumes a volume of only 1.5" x 1.8" x 0.9".
  • CC2538EM Reference Design
    CC2538EM-RD: This 2.4 GHz RF Layout Reference Design demonstrates good decoupling and layout techniques for a low power RF device operating in the license free 2.4 GHz frequency band.
  • Distance and Weight Measurement Using Inductive Sensing Reference Design
    TIDA-00215: The Distance and Weight Measurement Using Inductive Sensing Reference Design is a sub-system design which converts a distance measurement to a weight measurement. This design is intended as a reference design for building automation and weigh scale applications. In mechanical systems, there are many situations that require precise and accurate measurements of distance. One such scenario is the conversion of a distance measurement to a weight measurement, through the use of springs with well-known characteristics. This reference design enables weight and distance measurements to be incorporated into end systems, without the use of expensive magnets or other sensing materials.
  • SimpleLink™ ZigBee® Network Range Extender Reference Design
    CC2530-CC2592EM-RD: ZigBee applications such as home and industrial automation, lighting, metering, and sensor networks could need longer RF transmission range and better sensitivity than the stand-alone CC2530 can offer. TI's new SimpleLink CC2530-CC2592 reference design pairs the cost-effective SimpleLink ZigBee CC2530 wireless MCU with SimpleLink CC2592 range extender improving the receiver sensitivity by 2-3 dB and increasing the total link budget to 120 dB, enabling significant improvements in the range of each node in the ZigBee network.
  • 85 to 265VAC Input 4W Dual Output 12 and 3.3V Flyback Reference Design
    PMP9213.1: This 4W reference design generates both a 3.3V and 12V output. The 3.3V output is regulated, while the 12V output has some load dependent variation. The UCC28740 flyback controller provides a low cost yet efficient solution.
  • Synchronization of JESD204B Giga-Sample ADCs using Xilinx Platform for Phased Array Radar Systems
    TIDA-00432: This system level design shows how two ADC12J4000 evaluation modules (EVMs) can be synchronized together using a Xilinx VC707 platform. The design document describes the required hardware modifications and device configurations, including the clocking scheme. Example configuration files are shown for each EVM. The FPGA firmware is described and the relevant Xilinx IP block configuration parameters are shown. Data taken on the actual hardware is shown and analyzed, showing synchronization within 50 ps without characterized cables or calibrated propagation delays.
  • SimpleLink™ ZigBee® Network Range Extender Reference Design - CC2530-CC2592EM-RD - TI Tool Folder
    CC2530-CC2592EMK-RD: ZigBee applications such as home and industrial automation, lighting, metering, and sensor networks could need longer RF transmission range and better sensitivity than the stand-alone CC2530 can offer. TI's new SimpleLink CC2530-CC2592 reference design pairs the cost-effective SimpleLink ZigBee CC2530 wireless MCU with SimpleLink CC2592 range extender improving the receiver sensitivity by 2-3 dB and increasing the total link budget to 120 dB, enabling significant improvements in the range of each node in the ZigBee network.
  • Automotive ADAS Power Design Optimized for Xilinx® Zynq® 7020 SoC
    TIDA-00390: The TIDA-00390 design is an optimized power solution for Xilinx® Zynq® 7020 FPGA/SoC (out of the Zynq® 7000 series family of products). It targets ADAS applications where customers opt to use FPGA instead of Multicore DSP or MPU. This design runs from a single intermediate 3.3V or 5V power supply rail and provides a complete solution to power the Xilinx® Zynq® 7020. DDR memory termination and a 5V supply for a CAN Transceiver are also implemented. A LM3880 provides power up and power down sequencing. The design is tested and optimized for automotive applications.
  • Optical Heart Rate + Pedometer Reference Design on ARM Based Platform
    TIDA-00682: The TIDA-00682 reference design demonstrates how biometric sensors in a watch form factor can be used to obtain a person's heart rate and steps in real time. By combining the AFE4404 front-end IC and the InvenSense ICM-20655 with the ultra-low power processing capability of the wireless CC2650, it is possible to measure step count activity plus a very robust and high performance optical heart rate signal on an ARM based platform.
  • 85 to 265VAC Input 4W Dual Output 12 and 3.3V Flyback Reference Design
    PMP9213.2: This 4W reference design generates both a 3.3V and 12V output. The 3.3V output is regulated, while the 12V output has some load dependent variation. The UCC28740 flyback controller provides a low cost yet efficient solution.
  • Clocking Solution Reference Design for GSPS ADCs
    TIDA-00359: Low cost, high performance clocking solution for GSPS data converters. This reference design discusses the use of a TRF3765, a low noise frequency synthesizer, generating the sampling clock for a 4 GSPS analog-to-digital converter (ADC12J4000). Experiments demonstrate data sheet comparable SNR and SFDR performance.
  • 8V-36V Input 12V/7A; Active Clamp Forward Reference Design
    PMP5123: This reference design generates an isolated 12V/7A output from an 8V to 36V DC input. The UCC2897A controls an active clamp forward converter power stage. The low gate charge and low RDSon of the CSD19533Q5A and CSD19534Q5A allow this design to achieve a max load efficiency over 93%, with a peak efficiency of over 94%. The compact UCC27511 drivers simplify the gate drive circuitry for the synchronous rectifiers.
  • 85 to 265VAC Input 4W Dual Output 12 and 3.3V Flyback Reference Design - PMP9213.2 - TI Tool Folder
    PMP9213: This 4W reference design generates both a 3.3V and 12V output. The 3.3V output is regulated, while the 12V output has some load dependent variation. The UCC28740 flyback controller provides a low cost yet efficient solution.
  • Portable ZigBee Plug-In Software Framework for any OS
    TIDC-ZNP-HOST-SW3: A portable host software framework that allows ZigBee to be “bolted on” to existing products in the market, quickly enabling Internet of Things (IoT) system applications. This design can be used with any microcontrollers or processors, offering flexibility in the solution. This software framework design allows easy integration of applications on any operating system. Combined with the richness of intuitive application examples and a complete and simple API set, it allows easy integration as well as fast prototyping and product development.

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