MA240020 Microchip Technology, MA240020 Datasheet - Page 26
MA240020
Manufacturer Part Number
MA240020
Description
PIC24FJ64GA104 PIM W/ NanoWatt XLP
Manufacturer
Microchip Technology
Series
PIC®r
Datasheet
1.MA240020.pdf
(32 pages)
Specifications of MA240020
Tool / Board Applications
General Purpose MCU, MPU, DSP, DSC
Mcu Supported Families
PIC24F
Supported Devices
PIC24FJ64GA104
Development Tool Type
Hardware - Daughter Card
Accessory Type
Plug in module
Silicon Manufacturer
Microchip
Core Architecture
PIC
Core Sub-architecture
PIC24
Silicon Core Number
PIC24F
Silicon Family Name
PIC24FJxxGAxxx
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
For Use With/related Products
Explorer 16 (DM240001 or DM240002)
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Available stocks
Company
Part Number
Manufacturer
Quantity
Price
Company:
Part Number:
MA240020
Manufacturer:
MICROCHIP
Quantity:
12 000
Power Conversion and Motor Control Application Software
26
Application Type
Brushless DC Motor
Control
AC Induction Motor
Control
Permanent Magnet
Syncronous Motor
Control
Stepper Motor
Control
SMPS/Digital Power
Class B Software
Application Solution
Sensored BLDC Motor Control
Sensorless BLDC Motor Control Using the
dsPIC30F of dsPIC33F
Sensorless BLDC Control with Back-EMF Filtering
Sensorless BLDC Control with Back-EMF Filtering
Using a Majority Function
Vector Control of an ACIM using Optical Encoder
Introduction to ACIM Control
Sensorless Field Oriented Control (FOC) of an AC
Induction Motor (ACIM)
Sensorless Field Oriented Control (FOC) of an AC
Induction Motor (ACIM) Using Field Weakening
Sinusoidal PMSM Motor Control
Sensorless Field-Oriented Control for PMSM
Motors with field weaking using Slide Mode
Controller
Sensorless Field Oriented Control (FOC) of an AC
Induction Motor (ACIM) Using Field Weakening
Sensorless Field Oriented Control (FOC) for a
Permanent Magnet Synchronous Motor (PMSM)
Using a PLL Estimator and Field Weakening (FW)
Integrated Power Factor Correction (PFC) and
Sensorless Field Oriented Control (FOC) System
Single-Shunt Three-Phase Current Reconstruction
Algorithm for Sensorless FOC of a PMSM
Stepper Motor Control with dsPIC® DSCs
Switch Mode Power Supply (SMPS) Topologies
(Part I)
Switch Mode Power Supply (SMPS) Topologies
(Part II)
Offline UPS Reference Design
Digital Power Interleaved PFC Reference Design
Class B Safety Software Library for PIC MCUs and
dsPIC DSCs
16-bit Embedded Control Solutions
AN1083
AN1160
AN1162
AN1206
AN1017
AN1078
AN1206
AN1292
AN1208
AN1299
AN1307
AN1114
AN1207
AN1279
AN1278
AN1229
Number
AN957
AN901
AN908
AN984
AN
Description
This application note describes a fully-tested 3-phase BLDC motor control algorithm
with 3 Hall-effect sensors.
This application note describes how to provide sensorless BLDC motor control with
the dsPIC DSC device.
This application note describes how to apply a dsPIC DSC to control a sensorless
BLDC motor, using the dsPIC30F6010A device on a dsPICDEM™ MC LV board
platform.
This application note describes a sensorless Brushless Direct Current (BLDC) motor
control algorithm, implemented using the dsPIC® Digital Signal Controller (DSC).
The algorithm works by the use of a majority function for digitally filtering the Back-
Electromotive Force (BEMF). Each phase of the motor is filtered to determine when to
commutate the motor drive voltages.
This application note describes a fully-tested vector, or field oriented, control algorithm
for a 3-phase ACIM. The motor currents, torque and velocity are regulated in control
loops.
This application note describes volts per hertz control of an AC Induction Motor.
This application note presents a solution for sensorless Field Oriented Control (FOC)
of induction motors using a dsPIC® Digital Signal Controller (DSC). The benefits of
field oriented control can be directly realized as lower energy consumption, higher
efficiency, lower operating costs and reduced cost of drive components.
This application note presents one solution for sensorless Field Oriented Control
(FOC) with Field Weakening (FW) of induction motors using a dsPIC Digital Signal
Controller (DSC).
This application note provides a fully working and highly flexible solution for using
the dsPIC DSC to control a permanent magnet synchronous motor using three hall
sensors with sinusoidal voltages.
This application note describes how to apply a dsPIC DSC to control a permanent
magnet synchronous motor using the field oriented control algorithm. Shunt resistors
are used to estimate rotor position.
This application note presents one solution for sensorless Field Oriented Control
(FOC) with Field Weakening (FW) of induction motors using a dsPIC Digital Signal
Controller (DSC).
This application note desribes the sensorless FOC algorithm for PMSM motor using a
Phase Locked Loop (PLL) position and speed estimators.
This application note describes the process of integrating two complex applications:
PFC and Sensorless FOC. These applications are implemented on a Permanent
Magnet Synchronous Motor (PMSM). In addition, this application note also describes
the integration of the algorithms, lists the necessary hardware requirements, and
provides the guidelines to optimize the development procedure.
This dsPIC33F application note describes a motor control technique where a single-
shunt resistor circuit is used to measure the motor phase current.
This application note describes how to drive a stepper motor with a dsPIC33F motor
control family DSC.
This application note explains the basics of different types of SMPS topologies and
their applications. The pros and cons of different SMPS topologies are also explained
to guide the user to select an appropriate topology for a given application, while
providing useful information regarding selection of components for a given SMPS
design.
This application note is the second of a two-part series on Switch Mode Power
Supply (SMPS) topologies. This series expands on the previous material in Part I, and
presents the basic tools needed to design a power converter.
The application note describes the design of an Offline Uninterruptible Power Supply
(UPS) using a Switch Mode Power Supply (SMPS) dsPIC® Digital Signal Controller (DSC).
The application note describes the design of an Digital Power Interleaved PFC (IPFC)
using a Switch Mode Power Supply (SMPS) dsPIC® Digital Signal Controller (DSC).
This application note describes the Class B Safety Software Library routines that
detect the occurrence of Faults in a single channel CPU. These routines have been
developed in accordance with the IEC 60730 standard to support the Class B
certification process.
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