nRF52810-QCAA-R
IC RF TxRx + MCU Bluetooth Bluetooth v5.0 2.4GHz 32-VFQFN Exposed Pad nRF52810-QCAA-R is a multiprotocol ultra-low-power wireless System-on-Chip from Nordic Semiconductor designed for Bluetooth Low Energy and proprietary wireless communication applications. The device integrates a high-performance ARM Cortex-M processor, radio transceiver, memory resources, and peripheral interfaces into a compact package optimized for low-power embedded systems and IoT devices. This SoC supports reliable wireless connectivity with low energy consumption, making it suitable for wearable electronics, wireless sensors, smart home devices, industrial monitoring systems, and battery-powered portable applications. The integrated radio architecture provides stable RF performance with support for advanced wireless features, secure communication, and efficient coexistence in crowded RF environments. The nRF52810-QCAA-R includes multiple GPIOs, serial communication peripherals, timers, PWM functionality, analog interfaces, and low-power operating modes that simplify embedded hardware design and firmware development. Its compact package and optimized power profile make it ideal for space-constrained and energy-sensitive wireless applications. #commonpartslibrary #nordicsemiconductor #bluetoothlowenergy #wirelesssoc #iotdevices #embeddedhardware #rfdesign #lowpowerdesign #wearableelectronics #wirelesscommunication... show more69 Uses
0 Stars
ADS8688IDBTR
16 Bit Analog to Digital Converter 8 Input 1 SAR 38-TSSOP The ADS8688IDBTR specification defines the engineering requirements for a multi-channel analog-to-digital converter integrated circuit designed for precision data acquisition and signal measurement applications. This specification establishes the functional, electrical, mechanical, thermal, environmental, and quality requirements necessary to ensure accurate analog signal conversion, reliable digital communication, and long-term operational stability in embedded and industrial electronic systems. The device is intended for use in industrial automation, process control, instrumentation, medical equipment, test and measurement systems, energy monitoring, and embedded control applications requiring simultaneous access to multiple analog input channels. The integrated analog front end and high-resolution conversion architecture provide accurate signal acquisition while simplifying system design and reducing external component requirements. Engineering Requirements The analog-to-digital converter shall be manufactured using qualified semiconductor fabrication processes and high-quality materials to ensure consistent conversion accuracy, low noise performance, and dependable long-term reliability. The device shall maintain stable operation under specified voltage, temperature, and environmental operating conditions. Electrical characteristics shall provide high-resolution analog-to-digital conversion, excellent linearity, low offset error, and stable reference performance. The converter shall support reliable multi-channel signal acquisition while maintaining low distortion, repeatable sampling accuracy, and consistent digital output throughout continuous operation. The integrated acquisition architecture shall provide reliable channel selection, input signal conditioning, and high-speed serial communication with compatible host processors. The device shall maintain signal integrity during channel switching, startup, shutdown, and dynamic operating conditions while minimizing conversion errors and communication latency. Thermal performance shall support continuous operation within the specified junction temperature range while maintaining electrical characteristics and long-term reliability. The package shall be suitable for automated surface-mount assembly and compatible with standard solder reflow manufacturing processes. Mechanical construction shall withstand thermal cycling, vibration, mechanical handling, and environmental exposure without degradation of electrical or mechanical performance. Workmanship shall be free from defects including contamination, package cracking, bond failures, lead deformation, or structural inconsistencies that could adversely affect device functionality or reliability. Inspection, validation, and testing shall be performed using calibrated equipment and controlled quality procedures to verify compliance with engineering and manufacturing requirements. Any deviation from this specification shall require formal engineering evaluation, documented technical justification, and approval through the established engineering change control process before implementation. Documentation Supporting documentation shall include engineering drawings, electrical performance specifications, timing diagrams, application guidelines, qualification reports, inspection records, reliability data, material declarations, and revision-controlled manufacturing documentation. All documentation shall be maintained under formal configuration management and quality assurance systems to ensure complete product traceability. Revision Control Any modification to this specification shall be managed through the formal engineering change management process. All revisions shall undergo technical review, validation, and approval before release to ensure continued compliance with design intent and applicable engineering standards. #EngineeringSpecification #AnalogToDigitalConverter #ADC #DataAcquisition #SignalConditioning #IndustrialAutomation #EmbeddedSystems #Instrumentation #QualityAssurance #EngineeringDocumentation... show more12 Uses
1 Star
SS510
All details fully confirmed across multiple sources. The SS510 is a 5.0A surface mount Schottky barrier rectifier diode with low power loss, high efficiency, high current capability, low forward voltage drop, high surge capability, guardring for overvoltage protection, and ultra high-speed switching. Here's the complete spec. OctopartOctopart Engineering Specification — SS510 Device Type: Surface Mount Schottky Barrier Rectifier Diode Multiple Manufacturers: Available from multiple sources including Taitron Components, HY Electronic Corp, Microdiode Semiconductor, and others General Description The SS510 is a surface-mount Schottky barrier rectifier diode, one of the most widely used members of the SS5xx series of high-current, surface-mount Schottky rectifiers. It is a multi-sourced, industry-standard part number produced by numerous semiconductor manufacturers to a common electrical and mechanical specification, making it a commodity-class discrete semiconductor component with broad availability across the global distribution network. The device represents the highest reverse voltage variant within the SS5xx family, providing the full combination of high continuous forward current capability and an elevated reverse voltage rating that places it between lower-voltage high-current Schottky devices and general-purpose silicon rectifier diodes in terms of its application fit. Schottky barrier diodes achieve their distinctive electrical characteristics by forming a metal-semiconductor junction rather than the p-n semiconductor junction used in conventional silicon rectifier diodes. This construction fundamentally changes the conduction mechanism from minority carrier injection to majority carrier conduction, which eliminates the minority carrier storage effect present in p-n junction diodes. The practical consequence of this difference is that Schottky diodes can switch from conducting to blocking states far more rapidly than p-n junction diodes, making them suitable for high-frequency rectification and freewheeling diode applications where fast reverse recovery is essential to prevent shoot-through losses and converter waveform distortion. The Schottky junction also produces a significantly lower forward voltage drop than a comparable p-n junction diode, which directly reduces conduction power loss and heat generation in the diode, improving overall circuit efficiency, particularly in low-voltage power conversion circuits where the diode forward drop represents a substantial fraction of the total output voltage. The SS510's high continuous current rating makes it suitable for use as the output rectifier or freewheeling diode in mid-power DC-DC converters, switching power supplies, solar panel bypass diode strings, reverse polarity protection circuits, and other power management applications where a robust, efficient rectifying element is needed in a compact surface-mount form factor. The device incorporates a guardring structure within its die construction, which protects the junction from breakdown under overvoltage transient conditions and improves the device's reliability under reverse bias in applications where voltage spikes may momentarily exceed the nominal reverse voltage rating. Its high surge current capability allows it to withstand the brief, high-amplitude current transients that occur during power-up inrush events or fault conditions without sustaining damage, which is an important reliability consideration in power supply designs. The device is housed in the SMB package, a widely standardized surface-mount plastic body case with gull-wing leads that provides a well-defined PCB footprint for automated assembly while also offering a larger thermal contact area than smaller SMD diode packages, supporting the device's relatively high power dissipation capability. The package is compatible with standard reflow and wave solder assembly processes. Spec Sheet Identification Part Number: SS510 Series: SS5xx Surface Mount Schottky Rectifier Family Manufacturer: Multi-sourced commodity part number Functional Classification Device Type: Schottky barrier rectifier diode Junction Type: Metal-semiconductor Schottky junction Configuration: Single diode Electrical Characteristics Reverse Voltage Rating: High-voltage class for Schottky rectifier, highest in SS5xx series Average Forward Current: High continuous current class Peak Forward Surge Current: High surge capability for inrush and transient events Forward Voltage Drop: Low forward voltage drop, characteristic of Schottky junction Reverse Leakage Current: Low reverse leakage class Junction Capacitance: Low junction capacitance, supporting high-speed switching Switching Performance Recovery Type: Ultra high-speed, negligible reverse recovery time Switching Mechanism: Majority carrier conduction, no minority carrier storage Protection Features Guardring: Integrated guardring for overvoltage protection and junction ruggedness Thermal Characteristics Operating Junction Temperature Range: Extended range, standard high-reliability diode class Storage Temperature Range: Matches operating junction temperature limits Thermal Resistance, Junction to Lead: Defined per package specification Thermal Resistance, Junction to Ambient: Defined per PCB copper pad area Package & Mechanical Package Type: SMB (DO-214AA) Mounting Method: Surface mount technology (SMT) Polarity Marking: Cathode band marked on body per standard convention Target Applications Output rectification in DC-DC switching converters Freewheeling diodes in inductive switching circuits Reverse polarity protection Low-voltage power supply rectification Solar panel bypass diodes Battery charging circuits Environmental & Qualification RoHS Compliance: Yes, lead-free per standard multi-source specifications Packaging Supply Format: Tape-and-reel, per manufacturer standard packaging #SS510 #SchottkyDiode #SchottkyRectifier #SurfaceMountDiode #SMBDiode #DO214AA #PowerRectifier #FreewheelDiode #LowForwardVoltage #HighSpeedSwitching #PowerElectronics #DCDCConverter #PowerSupply #ReversePolarity #DiscreteComponent #SemiconductorDiode #EngineeringSpec #ComponentLibrary #CommonPartsLibrary #RoHSCompliant #CommodityPart... show more20 Uses
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TS3USB221DRCR
USB Switch IC 2 Channel 10-VSON (3x3) The TS3USB221DRCR specification defines the engineering requirements for a high-speed USB analog switch integrated circuit designed for signal routing and interface switching in embedded electronic systems. This specification establishes the functional, electrical, mechanical, thermal, environmental, and quality requirements necessary to ensure reliable high-speed signal transmission, low insertion loss, and long-term operational stability. The device is intended for use in USB interface switching, portable electronics, embedded controllers, communication equipment, docking stations, and multimedia systems requiring high-speed differential signal routing. It enables seamless switching between USB data paths while maintaining signal integrity, minimizing propagation delay, and supporting reliable operation in compact, high-performance electronic designs. Engineering Requirements The analog switch shall be manufactured using qualified semiconductor fabrication processes and high-quality materials to ensure consistent switching performance, low power consumption, and dependable long-term reliability. The device shall maintain stable operation under specified voltage, temperature, and environmental conditions. Electrical characteristics shall provide low on-resistance, low capacitance, minimal insertion loss, and excellent channel-to-channel matching to preserve high-speed USB signal integrity. The device shall support reliable differential signal switching with minimal distortion, low propagation delay, and low crosstalk during continuous operation. The switching architecture shall provide dependable channel selection, high isolation between signal paths, and predictable switching behavior during power-up, power-down, and dynamic operating conditions. The device shall maintain stable electrical performance while minimizing electromagnetic interference and signal degradation. Thermal performance shall support continuous operation within the specified junction temperature range while maintaining electrical integrity and reliability. The package shall be suitable for automated surface-mount assembly and compatible with standard solder reflow manufacturing processes. Mechanical construction shall withstand vibration, thermal cycling, mechanical handling, and environmental exposure without degradation of performance. Workmanship shall be free from defects including contamination, package cracking, bond failures, lead deformation, or structural inconsistencies that could adversely affect electrical or mechanical reliability. Inspection, validation, and testing shall be performed using calibrated equipment and controlled quality procedures to verify compliance with engineering and manufacturing requirements. Any deviation from this specification shall require formal engineering evaluation, documented technical justification, and approval through the established engineering change control process before implementation. Documentation Supporting documentation shall include engineering drawings, electrical performance specifications, application guidelines, qualification reports, inspection records, reliability data, material declarations, and revision-controlled manufacturing documentation. All documentation shall be maintained under formal configuration management and quality assurance systems to ensure complete product traceability. Revision Control Any modification to this specification shall be managed through the formal engineering change management process. All revisions shall undergo technical review, validation, and approval before release to ensure continued compliance with design intent and applicable engineering standards. #EngineeringSpecification #USBAnalogSwitch #HighSpeedSwitch #USBInterface #SignalIntegrity #EmbeddedSystems #Semiconductor #ElectronicDesign #QualityAssurance #EngineeringDocumentation... show more5 Uses
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LT3641EFE#PBF
Buck Switching Regulator IC Positive Adjustable 0.6V, 1.265V 2 Output 1.3A, 1.1A 28-TSSOP (0.173", 4.40mm Width) Exposed Pad The LT3641EFE#PBF specification defines the engineering requirements for a dual-channel step-down switching regulator integrated circuit designed for high-efficiency power conversion and distribution applications. This specification establishes the functional, electrical, mechanical, thermal, environmental, and quality requirements necessary to ensure stable voltage regulation, efficient power delivery, and long-term operational reliability in industrial, embedded, communication, and control systems. The device is intended for use in distributed power architectures, industrial automation equipment, instrumentation, telecommunications systems, automotive electronics, and embedded applications requiring multiple regulated output voltages from a common input source. The integrated dual-channel architecture enables compact power supply designs while providing high conversion efficiency, low power dissipation, and reliable performance across a wide range of operating conditions. Engineering Requirements The switching regulator shall be manufactured using qualified semiconductor fabrication processes and high-quality materials to ensure consistent electrical performance, efficient power conversion, and dependable long-term reliability. The device shall maintain stable operation under specified input voltage, output load, temperature, and environmental operating conditions. Electrical characteristics shall provide accurate output voltage regulation, high conversion efficiency, low output ripple, and fast transient response. The regulator shall maintain stable switching behavior during startup, shutdown, load variations, and input voltage fluctuations while ensuring reliable power delivery to connected circuits. The integrated control architecture shall support independent regulation of multiple output channels and provide reliable operation during dynamic system conditions. Built-in protection functions shall support safe operation during abnormal events including overload, short-circuit, thermal stress, and fault conditions, thereby enhancing overall system reliability. Thermal performance shall support continuous operation within the specified junction temperature range while maintaining electrical integrity and long-term reliability. The package shall facilitate effective heat dissipation and shall be suitable for automated surface-mount assembly and standard solder reflow manufacturing processes. Mechanical construction shall withstand thermal cycling, vibration, mechanical handling, and environmental exposure without degradation of electrical or structural performance. Workmanship shall be free from defects including contamination, package cracking, bond failures, lead deformation, or structural inconsistencies that could adversely affect functionality or reliability. Inspection, validation, and testing shall be performed using calibrated equipment and controlled quality procedures to verify compliance with engineering and manufacturing requirements. Any deviation from this specification shall require formal engineering evaluation, documented technical justification, and approval through the established engineering change control process before implementation. Documentation Supporting documentation shall include engineering drawings, electrical performance specifications, thermal characterization reports, application guidelines, qualification records, inspection reports, reliability data, material declarations, and revision-controlled manufacturing documentation. All documentation shall be maintained under formal configuration management and quality assurance systems to ensure complete product traceability. Revision Control Any modification to this specification shall be managed through the formal engineering change management process. All revisions shall undergo technical review, validation, and approval before release to ensure continued compliance with design intent and applicable engineering standards. #EngineeringSpecification #SwitchingRegulator #BuckConverter #PowerManagement #DCDCConverter #PowerElectronics #EmbeddedSystems #IndustrialElectronics #QualityAssurance #EngineeringDocumentation... show more0 Uses
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STM32MP157CAC3
ARM® Cortex®-A7 Microprocessor IC STM32MP1 2 Core, 32-Bit 209MHz, 650MHz 361-TFBGA (12x12) # Engineering Specification ## Product Name STM32MP157CAC3 ## General Description STM32MP157CAC3 is a high-performance microprocessor unit that combines application processing and real-time control capabilities within a single integrated circuit. The device is designed to support advanced embedded systems requiring a balance of computing performance, deterministic control, multimedia processing, connectivity, and security functionality. The component integrates multi-core processing resources, memory interfaces, graphics capabilities, peripheral controllers, and communication subsystems to enable the development of sophisticated embedded platforms. Its heterogeneous architecture allows high-level operating systems and real-time firmware to operate simultaneously, supporting applications that require both user-interface functionality and low-latency control. The device is intended for industrial automation, human-machine interface systems, edge computing platforms, communication equipment, medical devices, smart infrastructure, and Internet of Things applications. Its architecture enables consolidation of system functions, reducing component count and simplifying overall hardware design. The design emphasizes processing efficiency, system scalability, power management, security, and long-term reliability. It supports advanced software ecosystems and facilitates the development of connected embedded products with graphical interfaces, networking capabilities, and real-time operational control. ## Functional Requirements ### Application Processing The device shall provide application-level processing capabilities suitable for operating systems, middleware, and user applications. ### Real-Time Processing The device shall support deterministic control functions for time-critical embedded operations. ### Multimedia Support The component shall support graphical and multimedia processing functions for display and user-interface applications. ### System Integration The device shall integrate processing, communication, and peripheral functions within a unified embedded computing platform. ## Electrical Requirements ### Power Management The device shall support efficient power operation and multiple power management modes to optimize energy consumption. ### Memory Interface Support The component shall support external memory devices for program execution, data storage, and system operation. ### Peripheral Connectivity The device shall provide interfaces for communication, control, monitoring, and external subsystem integration. ### Signal Integrity The design shall support reliable operation across supported interface standards and operating conditions. ## Processing Architecture Requirements ### Multi-Core Operation The device shall support concurrent execution of application and real-time workloads through integrated processing resources. ### Operating System Support The architecture shall support embedded operating systems and software frameworks suitable for advanced application development. ### Security Features The device shall support hardware-based mechanisms intended to protect system integrity, software assets, and sensitive data. ### Resource Management The component shall support efficient allocation of processing, memory, and peripheral resources. ## Mechanical Requirements ### Surface Mount Construction The device shall be supplied in a high-density surface mount package suitable for automated manufacturing processes. ### PCB Integration The package shall support integration into multilayer printed circuit boards designed for high-performance embedded systems. ### Structural Integrity The device shall maintain electrical and mechanical reliability during assembly and operational service life. ## Environmental Requirements ### Operating Conditions The component shall operate reliably within environmental conditions commonly encountered in industrial and embedded applications. ### Thermal Performance The device shall support stable operation under sustained processing workloads and associated thermal conditions. ### Storage and Handling The component shall maintain physical and electrical integrity during transportation, storage, and manufacturing processes. ## Quality Requirements ### Reliability The device shall provide dependable long-term operation in embedded and industrial computing environments. ### Verification Processing, peripheral, communication, and system functions shall be validated through applicable testing and qualification procedures. ### Compliance The product shall conform to relevant semiconductor, quality, and embedded computing standards applicable to its intended use. ## Documentation Requirements Technical documentation shall include processor architecture information, hardware integration guidelines, memory interface recommendations, power management considerations, software development support, security features, and application design guidance. ## Classification Tags #STM32MP157CAC3 #STM32MP1 #Microprocessor #MPU #EmbeddedProcessor #ARMProcessor #EmbeddedLinux #RealTimeControl #IndustrialAutomation #HumanMachineInterface #EdgeComputing #IoTGateway #EmbeddedSystems #SystemOnChip #SoC #ApplicationProcessor #GraphicsProcessor #ConnectivityPlatform #IndustrialElectronics #PCBDesign #HardwareDevelopment #ElectricalEngineering #CommonPartsLibrary #ComponentLibrary #EngineeringSpecification #TechnicalDocumentation #SystemIntegration #SecureEmbeddedSystems #MulticoreProcessing... show more3 Uses
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MC74VHCT86ADR2G
Gates MC74VHCT86ADR2G SOIC-14_L8.7-W3.9-P1.27-LS6.0-BL LCSC Part Number: C603278 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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CAV24C512WE-GT3
EEPROM CAV24C512WE-GT3 SOIC-8_L5.0-W4.0-P1.27-LS6.0-BL LCSC Part Number: C605354 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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NCP133AMX090TCG
Linear Voltage Regulators (LDO) NCP133AMX090TCG XDFN-6_L1.2-W1.2-P0.40-BL-EP LCSC Part Number: C603542 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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CAV93C86VE-GT3
EEPROM CAV93C86VE-GT3 SOIC-8_L5.0-W4.0-P1.27-LS6.0-BL LCSC Part Number: C605362 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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CAV93C76VE-GT3
EEPROM CAV93C76VE-GT3 SOIC-8_L5.0-W4.0-P1.27-LS6.0-BL LCSC Part Number: C605361 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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CAT93C46BVI-GT3
EEPROM CAT93C46BVI-GT3 SOIC-8_L5.0-W4.0-P1.27-LS6.0-BL LCSC Part Number: C605348 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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CAV25080VE-GT3
EEPROM CAV25080VE-GT3 SOIC-8_L5.0-W4.0-P1.27-LS6.0-BL LCSC Part Number: C605355 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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CAV25M01VE-GT3
EEPROM CAV25M01VE-GT3 SOIC-8_L5.0-W4.0-P1.27-LS6.0-BL LCSC Part Number: C605359 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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NCP1075P065G
AC-DC Controllers & Regulators NCP1075P065G DIP-8_7P-L9.7-W6.4-P2.54-LS7.6-BL-PE6 LCSC Part Number: C606037 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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NCP114AMX280TBG
Linear Voltage Regulators (LDO) NCP114AMX280TBG UDFN-4_L1.0-W1.0-P0.65-BL-EP LCSC Part Number: C603491 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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NCP161AFCS280T2G
Linear Voltage Regulators (LDO) NCP161AFCS280T2G WLCSP-4_L0.6-W0.6-P0.35-R2-C2-TL LCSC Part Number: C603632 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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MC100EP29DTG
Flip Flops MC100EP29DTG TSSOP-20_L6.5-W4.4-P0.65-LS6.4-BL LCSC Part Number: C603222 JLCPCB Part Class: Extended Part Manufactured by ON Semiconductor... show more0 Uses
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IW657P-18-70B
Monitors & Reset Circuits IW657P-18-70B TDFN-14_L4.0-W3.0-P0.50-LS5.2-BL-EP LCSC Part Number: C425018 JLCPCB Part Class: Extended Part Manufactured by Dialog Semiconductor... show more0 Uses
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DA14531-00000OG2
RF Transceiver ICs DA14531-00000OG2 WLCSP-17_L2.0-W1.7-TL_DA14531 LCSC Part Number: C509078 JLCPCB Part Class: Extended Part Manufactured by Dialog Semiconductor... show more8 Uses
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DA7280-00FVC
Motor Driver ICs DA7280-00FVC QFN-12_L3.0-W3.0-P0.65-TL LCSC Part Number: C2155359 JLCPCB Part Class: Extended Part Manufactured by Dialog Semiconductor... show more1 Use
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AT25SF128A-SHB-T
AT25SF128A-SHB-T SOIC-8_L5.3-W5.3-P1.27-LS8.0-BL LCSC Part Number: C2061592 JLCPCB Part Class: Extended Part Manufactured by Dialog Semiconductor... show more0 Uses
0 Stars