Dr. Vasan Prabhu Veeramani’s Post

Precision Meets Performance - Our HDI PCBs are designed for tomorrow's demands. Are you ready for the future of electronics? https://buff.ly/41NNecC #PCB #HDI #PCBassembly #PCBassemblyservices #PCBfabrication #PCBcomponents #PCBmanufacturing #PCBmanufacturer #Blindburiedcircuits

Diode SPICE model parameters enable designers to optimize circuit performance, leading to the design of reliable and cost-effective electronic systems: https://ow.ly/SGwU50UbPJR

Learn more in our blog post: Maximizing Electronic Component Reliability in Rigid-Flex PCB Designs https://hubs.li/Q02JKwck0

#100daysamplifierdesign Day89 Servo Motor Driver PCB Servo Motor Driver PCB is designed to control the operation of servo motors, which are used in precise motion control applications. Here’s a detailed look: Driver Circuitry: The PCB includes driver circuits that generate the control signals required for the servo motor. This typically involves pulse-width modulation (PWM) to adjust the motor’s position or speed. Feedback Mechanism: Servos often include feedback systems such as potentiometers or encoders that provide real-time data on the motor's position. The PCB must process this feedback to accurately control and adjust the motor's movements. Power Handling: Servo motors can draw significant current, so the PCB design must accommodate high-current traces and include appropriate power management components. Adequate heat dissipation and power regulation are essential to ensure reliable operation. Control Interface: The PCB may also include interfaces for communication with a microcontroller or external control system. This could involve serial communication lines or analog input/output connections for receiving control commands and providing feedback.

Current trends in the electric vehicle PCB Industry As electrical vehicle chargers(EVC) evolve, we too need to develop and evolve our PCB technology and designs as well.  With more complex and smaller sized EVCs being made, we’ve needed to find ways to use the limited space which is provided. This in turn means: - Higher density of circuit board and more layers through the PCB – this provides more circuitry for function and is necessary to support electronic product development - Thinner materials (PP/CCL) - Less space for connectors and 3D installs - PTH is not enough, so we therefore need laser drilled microvias and buried via’s that are smaller and connect selected layers rather than going through the whole PCB. This in turn increases number of interconnections - Smaller components and smaller features. Read our blog post about PCBs for EVCS and learn more about the trends & design considerations: https://lnkd.in/dt7JgaSH #NCAB #NcabGroup #ReliablePCBs # EVC #PcbsForEvc #PcbEvc

Current trends in the electric vehicle PCB Industry 🚚 As electrical vehicle chargers(EVC) evolve, we too need to develop and evolve our PCB technology and designs as well. With more complex and smaller sized EVCs being made, we’ve needed to find ways to use the limited space which is provided. This in turn means: - Higher density of circuit board and more layers through the PCB – this provides more circuitry for function and is necessary to support electronic product development - Thinner materials (PP/CCL) - Less space for connectors and 3D installs - PTH is not enough, so we therefore need laser drilled microvias and buried via’s that are smaller and connect selected layers rather than going through the whole PCB. This in turn increases number of interconnections - Smaller components and smaller features. Read our blog post about PCBs for EVCs and learn more about the trends & design considerations: https://lnkd.in/dt7JgaSH

#100daysamplifierdesign Day89  Servo Motor Driver PCB Servo Motor Driver PCB is designed to control the operation of servo motors, which are used in precise motion control applications. Here’s a detailed look: Driver Circuitry: The PCB includes driver circuits that generate the control signals required for the servo motor. This typically involves pulse-width modulation (PWM) to adjust the motor’s position or speed. Feedback Mechanism: Servos often include feedback systems such as potentiometers or encoders that provide real-time data on the motor's position. The PCB must process this feedback to accurately control and adjust the motor's movements. Power Handling: Servo motors can draw significant current, so the PCB design must accommodate high-current traces and include appropriate power management components. Adequate heat dissipation and power regulation are essential to ensure reliable operation. Control Interface: The PCB may also include interfaces for communication with a microcontroller or external control system. This could involve serial communication lines or analog input/output connections for receiving control commands and providing feedback.

DC Motor Speed Controller PCB. This project design utilizes a 555 IC timer to generate a PWM signal, allowing for adjustable speed control. The design features a diode, capacitor, viable resistor, and a DC motor. By modifying the resistor values, the duty cycle can be adjusted, enabling smooth speed control. This project showcases the power of PWM technique in motor control applications. #DCMotorSpeedController #ElectronicProductDevelopment #MechatronicsEngineering

Thorough analysis is crucial for effective EMI management in PCB design, emphasizing the importance of selecting low-speed devices and employing suitable driving/receiving circuitry to mitigate EMI risks.#circuitboardwiring #deviceselection #EMI #EMImanagement #PCBDESIGN

Infineon Technologies innovative Q-DPAK top-side cooled package addresses the most demanding application requirements for increased power density and thermal handling. Q-DPAK is a compact SMD, able to handle high current and reach a thermal performance comparable to a TO-247. Infineon Technologies Q-DPAK allows leveraging the full advantages of an SMD, limiting the drawbacks like the heat spread through the PCB and enables high flexibility in PCB design. In today’s SMD-based designs, the output power is restricted by the thermal limit of the PCB material because the heat must be dissipated through the board. Thanks to the topside cooling concept of Q-DPAK, the thermal decoupling of board and #semiconductor is possible. This allows higher chip temperatures, higher power densities and improves system lifetime. Learn more about Q-DPAK here - https://lnkd.in/dtqEdDCd