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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: GRM21BR61A106KE19L

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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.

Alternate Parts for: GRM21BR61A106KE19L

Part Number Description Manufacturer Compare
C0805C106K8PAL Capacitors CAPACITOR, CERAMIC, MULTILAYER, 10V, X5R, 10uF, SURFACE MOUNT, 0805, CHIP KEMET Corporation GRM21BR61A106KE19L vs C0805C106K8PAL

Resources and Additional Insights

Reference Designs

  • Altera Arria V SoC Power Supply Reference Design - PMP9360.6 - TI Tool Folder
    PMP9360: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design - PMP9353.7 - TI Tool Folder
    PMP9353: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.6: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.8: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Energy Harvester Booster Pack Reference Design
    TIDA-00588: The TIDA-00588 reference design is a BoosterPack that harvests energy from a wide variety of current sources or from the onboard solar cells to power any low-power TI LaunchPad. This design is a highly integrated power management solution that is well-suited for ultra-low power applications. There are three storage methods on this board: 1)A 47mF super capacitor, 2) a LIR2032 coin cell, and 3) an external battery connector. You can use the onboard solar cells or add your own AC or DC current source.
  • Extending Rail-to-Rail Output Range for Fully Differential Amplifiers to Include True Zero Volts
    TIDA-00187: Operational amplifiers (op amps) have been used for decades in signal conditioning circuits and measurement systems. An op amp that has an output spanning from negative to positive supply rail are generally referred to as rail-to-rail output (RRO) op amps. These devices have been used increasingly in portable systems to drive analog to digital converters (ADCs) where reducing power consumption while not sacrificing converter dynamic range is a key concern. While the task calls for the lowest power RRO op amps, circuit designers are finding out that rail-to-rail doesn’t exactly mean rail-to-rail. In reality the output is limited to a couple hundred millivolts within the rail depending on the loading. This problem is known as headroom and is the result of the RRO architecture. This application report focuses on using a low power RRO fully differential op amp (THS4531A) and low noise negative bias generator (LM7705) to achieve true zero volts in a ground referenced single supply system.
  • Refrigerator Damper and Fan Motor Control Solutions
    TIDA-00297: Refrigerators often use a damper to control airflow and a fan to provide circulation. While discrete solutions have been used for years, this TI Design uses integrated motor drivers that provide easy control, high performance, and full protection. The DRV8848 drives the stepper motor damper, and the DRV10983 drives the BLDC fan with quiet 180° commutation. The BLDC even has closed-loop speed control, using an MSP430G2553 and the DRV8812 for a PWM-based power supply. The whole solution uses a single-layer PCB. BLDC and stepper control example code is provided in the MCU firmware. Protection from over-current, over-temperature, and under-voltage are all integrated in the DRV devices.
  • Wi-Fi Enabled IoT Node with High Performance MCU Reference Design
    TIDM-TM4C129XWIFI: A system example to show how to build a Wi-Fi Node by integrating the TM4C1294 MCU from the TM4C product family and the CC3100 network processor. This reference design demonstrates the capability of remotely controlling MCU operation via the internet.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.4: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • SimpleLink™ Wi-Fi® Enabled NFC Card Reader
    CC3200_NFC_CARD_READER: This TI design combines TI’s Wireless microcontroller (CC3200) and the TRF7970 NFC BoosterPack from third party provider DLP Design, in order to emulate a near field communication (NFC) reader, which securely transfers the data scanned from an NFC card to any remote location or database, in real time over Wi-Fi networks. Disclaimer: DLP Design, Inc. is not associated with DLP® products of Texas Instruments.
  • Wi-Fi Enabled IoT Node With NFC Connection Handover Reference Design
    TIDM-TM4C129XNFC: Configuring Wi-Fi network connection parameters in embedded applications can be completed with a simple tap using NFC technology. This reference design illustrates NFC connection handover (pairing) and URL sharing with a Wi-Fi node using a TM4C1294 high-performance microcontroller, CC3100 network processor and TRF7970A NFC Transceiver or RF430CL330H NFC Transponder.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.2: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.5: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Microstepping Stepper Motor Control With MCU and Wi-Fi for IoT Reference Design
    TIDM-TM4C123IOTSTEPPERMOTOR: A system example to show how to control a stepper motor via Wi-Fi connectivity. The TM4C123x MCU is integarated with the DRV8833 stepper motor driver to drive the stepper moter in full step, half step and microstep (up to 256) modes. The SimpleLinkTM Wi-Fi CC3100 network processor is also integrated into the system to demostatrate the capability of remotely controlling MCU/stepper motor operation via the Internet.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.1: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design - PMP9353.1 - TI Tool Folder
    PMP9353: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.9: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.5: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.3: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.2: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.6: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Xilinx Zynq 7000 Series (XC7Z045) 20W Reference Design
    PMP10613.2: The PMP10613 reference design provides all the power supply rails necessary to power Xilinx® Zynq® 7000 series (XC7Z045) FPGA. This design uses several LMZ3 series modules, LDOs, and a DDR termination regulator to provide all the necessary rails to power the FPGA. It also features one LM3880 for power up and power down sequencing. This design uses a 12V input.
  • Xilinx Zynq 7000 Series (XC7Z045) 20W Reference Design
    PMP10613.1: The PMP10613 reference design provides all the power supply rails necessary to power Xilinx® Zynq® 7000 series (XC7Z045) FPGA. This design uses several LMZ3 series modules, LDOs, and a DDR termination regulator to provide all the necessary rails to power the FPGA. It also features one LM3880 for power up and power down sequencing. This design uses a 12V input.
  • Sync Boost 5V@4A for USB Battery Chargers
    PMP5417: PMP5417 is a high efficiency synchronous boost converter using the TPS43000. The 2.5V-4.2V input allows operation from a 3.3V source as well as a lithium-ion battery. The output power is 5V/4A.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.1: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.7: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.3: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.10: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Altera Cyclone V SoC FPGA Power Reference Design
    PMP9353: The PMP9353 reference design is a complete power solution for Altera Cyclone V SoC devices. This design uses several LMZ3 series modules , two LDOs, and a DDR termination regulator to provide all the necessary rails to power the SoC chip. This design also shows correct power-up sequencing.
  • Altera Arria V SoC FPGA Power Solution Reference Design
    PMP9360: The PMP9360 reference design is a complete power solution for Altera's Arria V™ SoC devices. This design uses several LMZ3 series modules , an LDO, and a DDR termination regulator to provide all the necessary rails to power the SoC chip. This design also shows correct power up sequencing.
  • Wi-Fi Camera Application for SimpleLink Wi-Fi CC3200 Launchpad
    TIDC-CC3200CAMBOOST: This SimpleLink Wi-Fi CC3200 Launchpad & Camera BoosterPack based design brings Wi-Fi camera capability to new applications as well as existing ones such as door bells. It enables the capture, remote control and transmission of JPEG (VGA or QVGA) images via Wi-Fi.
  • Altera Arria V SoC Power Supply Reference Design
    PMP9360.7: This reference design provides all the power supply rails necessary to power Altera's Arria V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.
  • Xilinx Zynq 7000 Series (XC7Z045) 20W Reference Design - PMP10613.1 - TI Tool Folder
    PMP10613: The PMP10613 reference design provides all the power supply rails necessary to power Xilinx® Zynq® 7000 series (XC7Z045) FPGA. This design uses several LMZ3 series modules, LDOs, and a DDR termination regulator to provide all the necessary rails to power the FPGA. It also features one LM3880 for power up and power down sequencing. This design uses a 12V input.
  • Charger Booster Pack Reference Design
    TIDA-00587: The TIDA-00587 reference design is a charger that has been designed as a booster pack to fit on the TI Launchpad development boards. The use of this this board for development will reduce the time spent in design and test of the bq24250 charger IC. You can charger your battery and using the on board electronic load you can discharge your battery. This will allow you to do cycle testing to measure your batteries performance and capabilities when charging with the bq24250 charger.
  • Altera Cyclone V SoC Power Supply Reference Design
    PMP9353.4: This reference design provides all the power supply rails necessary to power Altera's Cyclone V SoC FPGA. This design uses LMZ3 series modules to generate the rails to power the FPGA.

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