EVL6227-PLUGEvaluation kit environment for L62xx family of dual brush DC and stepper motor drivers based on STM32 Nucleo | Development Boards, Kits, Programmers | 1 | Active | The EVL62XX-MAIN is an expansion board that can host small EVL62XX-PLUG plug-in boards for quick and easy evaluation of brush DC and stepper motor drivers of the L62xx family.
These boards provide an affordable and easy-to-use solution to drive dual brush DC and bipolar stepper motors in association with the evaluation software STSPIN Studio.
The EVL62XX-MAIN is compatible with the Arduino UNO R3 connector. |
EVL6228-PLUGEvaluation kit environment for L62xx family of dual brush DC and stepper motor drivers based on STM32 Nucleo | Evaluation and Demonstration Boards and Kits | 1 | Active | The EVL62XX-MAIN is an expansion board that can host small EVL62XX-PLUG plug-in boards for quick and easy evaluation of brush DC and stepper motor drivers of the L62xx family.
These boards provide an affordable and easy-to-use solution to drive dual brush DC and bipolar stepper motors in association with the evaluation software STSPIN Studio.
The EVL62XX-MAIN is compatible with the Arduino UNO R3 connector. |
EVL62XX-MAINEvaluation kit environment for L62xx family of dual brush DC and stepper motor drivers based on STM32 Nucleo | Development Boards, Kits, Programmers | 1 | Active | The EVL62XX-MAIN is an expansion board that can host small EVL62XX-PLUG plug-in boards for quick and easy evaluation of brush DC and stepper motor drivers of the L62xx family.
These boards provide an affordable and easy-to-use solution to drive dual brush DC and bipolar stepper motors in association with the evaluation software STSPIN Studio.
The EVL62XX-MAIN is compatible with the Arduino UNO R3 connector. |
EVL6470Stepper motor driver evaluation board based on the L6470 | Development Boards, Kits, Programmers | 1 | Active | The EVL6470 is a stepper motor driver evaluation board based on the L6470.
It provides an affordable and easy-to-use solution to drive a stepper motor in your application.
The L6470 device, created using analog mixed signal technology, is an advanced, fully integrated solution suitable for driving two-phase bipolar stepper motors with microstepping. It integrates a dual low RdsONDMOS full bridge with an accurate on-chip current sensing circuitry suitable for non-dissipative current control and overcurrent protection. Thanks to a unique control system, a true 1/128-step resolution is achieved. The digital control core can generate user-defined motion profiles with acceleration, deceleration, speed, or target position, which are easily programmed through a dedicated set of registers. All commands and data registers, including those used to set analog values (that is: current control value, current protection trip point, dead time, PWM frequency, etc.) are sent through a standard 5-Mbit/s SPI. A complete set of protections (thermal, low bus voltage, overcurrent, and motor stall) fully protect the L6470 device, as required by the most demanding motor control applications.
The EVL6470 is compatible with the Arduino® UNO R3 connector, and it supports the addition of other boards, which can be stacked to drive up to three stepper motors. |
EVL6472Stepper motor driver evaluation board based on the L6472 device | Evaluation Boards | 1 | Active | The EVL6472 is a stepper motor driver evaluation board based on the L6472.
It provides an affordable and easy-to-use solution to drive a stepper motor in your application.
The L6472 device, created using analog mixed signal technology, is an advanced, fully integrated solution suitable for driving two-phase bipolar stepper motors with microstepping. It integrates a dual low RdsONDMOS full bridge with an accurate on-chip current sensing circuitry suitable for non dissipative current control and overcurrent protection. Thanks to a new current control, a 1/16-microstepping is achieved through an adaptive decay mode which outperforms traditional implementations. The digital control core can generate user-defined motion profiles with acceleration, deceleration, speed, or target position, which are easily programmed through a dedicated set of registers. All application commands and data registers, including those used to set analog values (that is: current control value, current protection trip point, dead time, etc.) are sent through a standard 5-Mbit/s SPI.A complete set of protections (thermal, low bus voltage and overcurrent) makes the L6472 device "bullet proof", as required by the most demanding motor control applications.
The EVL6472 is compatible with the Arduino® UNO R3 connector, and it supports the addition of other boards, which can be stacked to drive up to three stepper motors. |
EVL6480Stepper motor driver evaluation board based on the L6480 device | Evaluation Boards | 1 | Active | The EVL6480 is a stepper motor driver evaluation board based on the L6480.
It provides an affordable and easy-to-use solution to drive a stepper motor in your application.
The L6480 device, created using analog mixed signal technology, is an advanced, fully integrated solution suitable for driving two-phase bipolar stepper motors with microstepping. It integrates a dual full bridge gate driver for N-channel MOSFET power stages with embedded non-dissipative overcurrent protection. Thanks to a unique voltage driving mode, which compensates for BEMF, bus voltage, and motor winding variations, the microstepping of a true 1/128-step resolution is achieved. The digital control core can generate user-defined motion profiles with acceleration, deceleration, speed, or target position, which are easily programmed through a dedicated set of registers. All application commands and data registers, including those used to set analog values (that is: current protection trip point, dead time, PWM frequency, etc.) are sent through a standard 5-Mbit/s SPI. A complete set of protections (thermal, low bus voltage, overcurrent, and motor stall) makes the L6480 device "bullet proof," as required by the most demanding motor control applications.
The EVL6480 is compatible with the Arduino® UNO R3 connector and it supports the addition of other boards, which can be stacked to drive up to three stepper motors. |
EVL6482Stepper motor driver evaluation board based on the L6482 | Evaluation Boards | 1 | Active | The EVL6482 is a stepper motor driver evaluation board based on the L6482.
It provides an affordable and easy-to-use solution to drive a stepper motor in your application.
The L6482 device, created using analog mixed signal technology, is an advanced, fully integrated solution suitable for driving two-phase bipolar stepper motors with microstepping. It integrates a dual full bridge gate driver for N-channel MOSFET power stages with embedded non dissipative overcurrent protection. Thanks to a new current control, a 1/16-microstepping is achieved through an adaptive decay mode, which outperforms traditional implementations. The digital control core can generate user-defined motion profiles with acceleration, deceleration, speed, or target position, which are easily programmed through a dedicated set of registers. All application commands and data registers, including those used to set analog values (that is: current protection trip point, dead time, PWM frequency, etc.) are sent through a standard 5-Mbit/s SPI. A complete set of protections (thermal, low bus voltage, overcurrent, and motor stall) makes the L6482 device "bullet proof", as required by the most demanding motor control applications.
The EVL6482 is compatible with the Arduino® UNO R3 connector and it supports the addition of other boards, which can be stacked to drive up to three stepper motors. |
| Development Boards, Kits, Programmers | 1 | Active | |
EVL6562A-400WL6562A 400W FOT-controlled PFC pre-regulator evaluation board | Evaluation Boards | 1 | Active | The board implements a 400 W, wide-range mains input, PFC pre-conditioner suitable for ATX PSU, Flat screen displays, etc. To make possible the use of a low-cost device like the L6562A at this power level, usually prohibitive for TM PFC, the chip operates with Fixed-Off-Time control.
This allows continuous conduction mode operation, normally achievable with more expensive control chips and more complex control architectures. For technical details and demoboard performance, please refer to the available application note. |
| Evaluation Boards | 2 | Active | |
