ANALOG DEVICES MAX22210 Evaluation Kit User Guide

: June 13, 2024
: Analog Devices

Table of Contents

ANALOG DEVICES MAX22210 Evaluation Kit
Product Information
Product Usage Instructions
General Description
Benefits and Features
MAX22210 Evaluation Kit
- Software Installation
Detailed Description of Hardware
Ordering Information
MAX22210 EV Kit Bill of Materials
MAX22210 EV Kit Schematic
MAX22210 EV Kit PCB Layout
Revision History
References
Read User Manual Online (PDF format)
Download This Manual (PDF format)

ANALOG DEVICES MAX22210 Evaluation Kit

ANALOG-DEVICES-MAX22210-Evaluation-Kit-product

Product Information

Product Name: MAX22210 Evaluation Kit
Evaluates: MAX22210
Description: The MAX22210 evaluation kit (EV kit) provides a proven design to evaluate the +36V, 3.8A (peak) two-phase stepper motor driver. It can drive a single stepper motor and provides an onboard microcontroller (MCU) and GUI to drive the MAX22210’s inputs and configure the modes of operation. Microstep modes, decay modes, target speeds, and acceleration can also be configured using the GUI.
Benefits and Features:
- Easy Evaluation of the MAX22210 Stepper-Motor Driver
- On-Board +3.3V Regulator to Supply I/Os of the MAX22210
- Perforated Board and Headers Allow for Separation of the MAX22210 Circuit
- Fully Assembled and Tested
- Proven PCB Layout
Required Equipment:
- MAX22210 EV Kit
- USB Type-A to Micro USB Type-B Male Cable
- Up to +36V DC, 3.8A Power Supply
- Stepper Motor

Product Usage Instructions

Ensure the power supply of the MAX22210 is clamped below +42V to avoid damage to the motor-driver IC.
Verify that shunts are installed in the default positions.
Connect a stepper motor to the J6 terminal block.
Connect the MAX22210 EV kit board to the PC with a USB cable.
Launch the MAX22210 EV kit GUI.
Click on “Device” in the menu bar and select the COM port of the EV kit board.
- The GUI will display the Selected COM Port, Firmware Version, and Connected in the bottom status bar if the connection was successful.
Connect a supply (up to +36V) to the VM and adjust the VM voltage to the desired operating voltage.
Turn on the VM supply.
Click on the “WAKE” slider to wake the part from sleep mode.

General Description

The MAX22210 evaluation kit (EV kit) provides a proven design to evaluate the +36V, 3.8A (peak) two-phase stepper motor driver. The MAX22210 EV kit can drive a single stepper motor and provides an onboard microcon-troller (MCU) and GUI to drive the MAX22210’s inputs and configure the modes of operation. Microstep modes, decay modes, target speeds, and acceleration can also be configured using the GUI.

Benefits and Features

Easy Evaluation of the MAX22210 Stepper-Motor Driver
On-Board MCU and GUI to Drive and Configure the MAX22210
Configurable Target Speed
Configurable Acceleration Profiles
Configurable Microstepping and Decay Modes
Motor-Coil Current Reporting
Configurable Full-Scale Current
On-Board +3.3V Regulator to Supply I/Os of the MAX22210
Perforated Board and Headers Allow for Separation of the MAX22210 Circuit
Windows® 7-, 8-, 10-Compatible Software
Fully Assembled and Tested
Proven PCB Layout

MAX22210 Evaluation Kit

MAX22210 EV Kit Files

FILE	DESCRIPTION
MAX22210_GUI_setup_v1.2.3.exe	GUI Install File

Quick Start Required Equipment

MAX22210 EV Kit
USB Type-A to Micro USB Type-B Male Cable
Up to +36V DC, 3.8A Power Supply
Stepper Motor
It is recommended that the user reads the MAX22210 IC data sheet prior to using the EV kit and GUI.
Ordering Information appears at the end of the data sheet.

EV Kit Board

Software Installation

Note: In the following sections, software-related items are identified by bolding.
Text in bold refers to items directly from the EV kit software.

Follow the steps to install the GUI software:

Save the MAX22210_GUI_setup_v1.2.3.exe file to the user’s PC and double-click to begin the installation.
Click the Next button in the welcome screen to begin the GUI installation.
Select the install directory and Start Menu folder name.
When installation is complete, click the Finish button to launch the MAX22210 EV kit GUI.

Procedure

The EV kit is fully assembled and tested. Follow the steps below to verify board operation:

As with all motor-driver applications, stopping or braking the motor can cause a back EMF (BEMF) current and voltage surge. At high supply voltages, this can cause the supply to rise above the absolute maximum allowable voltage to the supply pins of a motor-driver IC. It is highly recommended that the power supply of the MAX22210 be clamped below
+ 42V to avoid damage to the motor-driver IC.
Verify that shunts are installed in the default positions.
Connect a stepper motor to the J6 terminal block.
Connect the MAX22210 EV kit board to the PC with a USB cable.
Launch the MAX22210 EV kit GUI.
Click on Device in the menu bar and select the COM port of the EV kit board.
- a. The GUI displays the Selected COM Port, Firmware Version, and Connected in the bottom status bar if the connection was a success.
Connect a supply (up to +36V) to VM and adjust the VM voltage to the desired operating voltage.
Turn on the VM supply.
Click on the WAKE slider to wake the part from sleep mode.
Click on the ENABLE slider to enable the part.
Select the following settings in the Motor Control Graph to begin the first run of the stepper motor.
- a. Target Speed (PPS) = 200
- b. Acceleration Rate (PPSPS) = 100
- c. Acceleration Starting/Ending Speed (PPS) = 100
- d. Steps to Stop = 100
- e. # of Steps = 500
- f. Select Full Step in the Step Mode dropdown
Click on the Move # of Steps slider and for a 200 steps/rotation, confirm that the motor shaft rotates three times with the appropriate acceleration and deceleration profile.

Table 1. Default Shunt Positions

HEADER	SHUNT POSITION	DESCRIPTION
J2	Not installed*	MCU debug header 1
J4	Not installed*	External +5V probe header
J8	Not installed*	MCU debug header 2
J9	Not installed*	External +3.3V probe header
J10	Not installed*	Debug RC capacitor isolation

J11

| 3-4| MAX22210 ISENA current output connected to MCU ADC input
5-6| MAX22210 ISENB current output connected to MCU ADC input
7-8| GND side of REF pin resistor connected to MCU DAC output. If left not installed, install a shunt on header J14 to connect the GND side of the RREF resistor to GND.
9-10| MAX22210 HFS input connected to MCU output
11-12| MAX22210 STEP input connected to MCU output
13-14| MAX22210 DIR input connected to MCU output
15-16| MAX22210 TRIGA output connected to MCU output
17-18| MAX22210 TRIGB output connected to MCU output
Pins 1 and 2| +3.3V sourced from LDO option from J13
Pins 19 and 20| GND
All not installed| Even row of pins allow access to the MAX22210 pins to be driven or monitored without the use of the on-board MCU

J12

| 3-4| MAX22210 DECAY1 input connected to MCU output
5-6| MAX22210 DECAY2 input connected to MCU output
7-8| MAX22210 FAULT output connected to MCU output
9-10| MAX22210 EN input connected to MCU input
11-12| MAX22210 SLEEP input connected to MCU output
13-14| MAX22210 MODE0 input connected to MCU output
15-16| MAX22210 MODE1 input connected to MCU output
17-18| MAX22210 MODE2 input connected to MCU output
Pins 1 and 2| +3.3V sourced from LDO option from J13
Pins 19 and 20| GND
All not installed| Even a row of pins allows access to the MAX22210 pins to be driven or monitored without the use of the on-board MCU

J13

| 1-2| +3.3V sourced from external +3.3V test point (TP8)
3-4*| +3.3V sourced from +5V USB VBUS voltage
5-6| +3.3V sourced from VM voltage
HEADER| SHUNT POSITION| DESCRIPTION
---|---|---

J14

| Not installed| Allows the MCU to adjust the GND side voltage of the MAX22210’s REF resistor. Leave this head not installed when using the GUI to control the full-scale current.
1-2| Connects the GND side voltage of the MAX22210’s 18kΩ REF resistor to GND. Install this header with a shunt if the GUI is not being used to control the full-scale current.
J7| Not installed| The MAX22210 outputs can be monitored using pins 1 through 4 of header J7

SW1

| 1-2 (upwards)*| Uses the USB VBUS voltage for the +5V to +3.3V LDO conversion
2-3 (downwards)| Uses an external +5V voltage applied to TP5 for the +5V to +3.3V LDO conversion

Indicates default position.

Detailed Description of Hardware

The MAX22210 EV kit provides a proven layout, evaluation circuit, and software to evaluate the MAX22210 (U1) IC. The EV kit features a DSPIC33CH512MP508T (U3) microcontroller (MCU), an MCP2221A (U4) USB-to-UART/I2C serial converter, and a MIC5528 (U6) +3.3V LDO that enables serial communication between the GUI and EV kit, provides power to the MCU circuit from the USB port, and allows the user to drive and configure the logic inputs of the MAX22210 IC. The EV kit has perforations down the middle of the board to separate the microcontroller from the MAX22210 circuit.
To operate the MAX22210 circuit without the use of the MCU or GUI, depopulate the shunts on headers J11 and J12 and install a shunt on header J14. This sets the maximum fixed IFS current to 2A. The maximum fixed IFS cur-
rent can be adjusted by changing the RREF resistor to a value from 12kΩ to 60kΩ as shown in the equation below
where KIFS = 36KV and HFS_VALUE = 1 when the HFS logic input pin is low, or HFS_VALUE = 0.5 when the HFS logic input pin is high:
The value of the full-scale current is proportional to the current flowing from the REF pin of the MAX22210 IC to GND through the RREF resistor. When using the MCU and GUI, the maximum fixed IFS current is scaled from 0% to 100% by applying a voltage (VREF) in the range of 0V to 0.9V to the GND side of the RREF resistor connected to pin 1 of header J14. The IFS value is determined using the following equation:

IFS(A) IFS_MAX(A) 0.9V VREF(V) 0.9V

Where IFS_MAX = the fixed maximum full-scale current (IFS) as configured by the RREF resistor on the EV kit board and VREF is the voltage applied to pin 1 of J14.
The EV kit board is shipped with RREF = 18kΩ, which sets the fixed maximum full-scale current to 2A or 1A depending on the state of the HFS pin. Refer to the MAX22210 IC data sheet for more information regarding the full-scale current settings.

Detailed Description of Software

The MAX22210 EV kit GUI allows the user to control and communicate with the MAX22210 IC using a PC.

Control Settings

The Control Settings group box allows the user to enable or disable the MAX22210 or enter and exit sleep mode (see Figure 4).

Motor-Control Graph

The Motor Control Graph group box allows the user to configure the speed and acceleration of the stepper motor (Figure 5).
The user can select the Target Speed (PPS), acceleration, and deceleration profiles (Acceleration
Rate (PPS) and Acceleration Starting/Ending Speed (PPS)), and number of steps to travel (# of Steps). The acceleration profiles have a starting speed and an ending speed which is user-defined with an acceleration rate that applies to both the acceleration ramp and deceleration ramp. The user can choose to have the motor stop after the # of Steps have been traveled, or an additional number of Steps to Stop can be added, which run after the deceleration profile is completed and the # of Steps have been traveled. Additional steps prior to the motor stop can be added by entering the value in the Steps to Stop field.

Start/Stop

The Start / Stop group box allows the user to move the motor in one of three modes (see Figure 6).
Enabling Free Running mode follows the acceleration profile used to reach the target speed and runs until Free Running mode is disabled.
Enabling Move # of Steps mode follows the acceleration and deceleration profiles (Acceleration Rate (PPS) and Acceleration Starting/Ending Speed (PPS)), Target Speed (PPS), and Steps to Stop selections until the number of steps and steps to stop have been traveled.
Enabling the Reciprocate mode follows the acceleration and deceleration profiles (Acceleration Rate (PPS) and Acceleration Starting/Ending Speed (PPS)), Target Speed (PPS), and Steps to Stop selections until the user-defined number of steps have been traveled and then reverses direction with the same behavior until the Reciprocate slider is disabled.

Status Output

The Status Output indicator shows the status of the FAULT pin (see Figure 7).
Under normal operation, the on-screen indicator is green. During fault conditions, the on-screen indicator is red.

Motor-Control Parameters

The Motor Control Parameters group box (Figure 8) allows the user to select the Step Mode, Decay Mode, motor current scaling factor (HFS_VALUE (HFS)), and motor direction (Direction DIR).
These parameters correspond to logic input pins on the MAX22210 IC, and the GUI allows the user to drive these pins through the onboard MCU. The Step Mode dropdown menu allows the user to select a step mode from Full Step up to 1/128 Step. See Table 2 for more details about the microstep modes. The Decay Mode dropdown menu allows the user to select from the various decay modes of the MAX22210. See Table 3 and the Adaptive Decay Modes section of the MAX22210 IC data sheet for more details about the decay modes. The HFS (output-current full scale) and Direction (DIR) selections allow the user to select the torque scal-ing factor and direction of rotation. The MCU drives the MAX22210 IC’s HFS and DIR pins according to the selections made.

Full-Scale Current

The Full Scale Current group box allows the user to scale the maximum full-scale current used to drive the stepper motor from 0% to 100% (see Figure 9). The maxi-mum full-scale current is set to 2A by the on-board RREF resistor and can be scaled using the I_FS slider.

Table 2. Step-Mode Selection

MODE2	MODE1	MODE0	STEP MODE
0	0	0	Full Step (71% Current)
0	0	1	1/2 Step
0	1	0	1/4 Step
0	1	1	1/8 Step
1	0	0	1/16 Step
1	0	1	1/32 Step
1	1	0	1/64 Step
1	1	1	1/128 Step

Table 3. Decay Modes

DECAY2	DECAY1	INCREASING STEPS	DECREASING STEPS
0	0	Slow	Slow
0	1	Mixed 30% Fast	Mixed 30% Fast
1	0	Mixed 60% Fast	Mixed 60% Fast
1	1	Adaptive	Adaptive

ANALOG-DEVICES-MAX22210-Evaluation-Kit-fig-8

Ordering Information

PART TYPE
- MAX22210EVKIT# EV KIT
Denotes RoHS compliant.

MAX22210 EV Kit Bill of Materials

ITEM| REF_DES| DNI/DNP| QTY| MFG PART #| MANUFACTURER| VALUE| DESCRIPTION| COMMENTS
---|---|---|---|---|---|---|---|---
1| C1| –| 1| CL05A105KO5NNN;

CC0402KRX5R7BB105

| SAMSUNG;YAGEO| 1UF| CAP; SMT (0402); 1UF; 10%; 16V; X5R;

CERAMIC

|
2| C2| –| 1| CGA3E2X7R2A223K080AA| TDK| 0.022UF| CAP; SMT (0603); 0.022UF; 10%; 100V;

X7R; CERAMIC

|
3| C3| –| 1| TMK105BJ105MV| TAIYO YUDEN| 1UF| CAP; SMT (0402); 1UF; 20%; 25V; X5R;

CERAMIC

|
4| C4, C16-C18, C25, C26| –| 6| GRT188R61C106KE13| MURATA| 10UF| CAP; SMT (0603); 10UF; 10%; 16V; X5R;

CERAMIC

|

5

| ****

C8

| ****

–

| ****

1

| GRM21BR70J106K; C2012X7R0J106K125AB;

CGA4J1X7R0J106K125AC

| MURATA;TDK;TDK| ****

10UF

| CAP; SMT (0805); 10UF; 10%; 6.3V; X7R; CERAMIC|
6| C9| –| 1| C0805C224K1RAC;

GRM21AR72A224KAC5

| KEMET;MURATA| 0.22UF| CAP; SMT (0805); 0.22UF; 10%; 100V; X7R;

CERAMIC

|

7

| ****

C10, C11

| ****

–

| ****

2

| C2012X7S2A105K125AB; GRJ21BC72A105KE11;

GRM21BC72A105KE01

| TDK;MURATA;MURATA| ****

1UF

| CAP; SMT (0805); 1UF; 10%; 100V; X7S; CERAMIC|

8

| ****

C12, C20, C23, C24, C27-C29, C34, C39, C45

| ****

–

| ****

10

| 885012206071; C1608X7R1E104K080AA; C0603C104K3RAC; GRM188R71E104KA01; C1608X7R1E104K;

06033C104KAT2A

| WURTH ELECTRONICS INC; TDK;KEMET;MURATA;TDK;AVX| ****

0.1UF

| ****

CAP; SMT (0603); 0.1UF; 10%; 25V; X7R; CERAMIC

|

9

| ****

C13-C15, C30, C32, C33, C35, C41, C46

| ****

–

| ****

9

| C0603X5R160-105KNP; EMK107BJ105KA; C1608X5R1C105K080AA; GRM188R61C105K; 0603YD105KAT2A;

CL10A105KO8NNN

| VENKEL LTD.;TAIYO YUDEN; TDK;MURATA;AVX;SAMSUNG ELECTRO-MECHANICS| ****

1UF

| ****

CAP; SMT (0603); 1UF; 10%; 16V; X5R; CERAMIC;

|

10

| ****

C19, C21

| ****

–

| ****

2

| GRM188R71A225KE15; CL10B225KP8NNN; C1608X7R1A225K080AC;

C0603C225K8RAC

| MURATA;SAMSUNG; TDK;KEMET| ****

2.2UF

| ****

CAP; SMT (0603); 2.2UF; 10%; 10V; X7R; CERAMIC

|
11| C22, C31, C37, C42,

C47

| –| 5| C1608C0G1E103J080AA| TDK| 0.01UF| CAP; SMT (0603); 0.01UF; 5%; 25V; C0G;

CERAMIC;

|
12| C36, C38, C40| –| 3| C1210C476M4PAC;

GRM32ER61C476ME15

| KEMET;MURATA| 47UF| CAP; SMT (1210); 47UF; 20%; 16V; X5R;

CERAMIC

|

13

| ****

C43

| ****

–

| ****

1

| C0603C474K4RAC; GRM188R71C474K; EMK107B7474KA;

C1608X7R1C474K080AC

| KEMET;MURATA;TAIYO YUDEN;TDK| ****

0.47UF

| ****

CAP; SMT (0603); 0.47UF; 10%; 16V; X7R; CERAMIC

|
14| C48| –| 1| 06033C104JAT2A| AVX| 0.1UF| CAP; SMT (0603); 0.1UF; 5%; 25V; X7R;

CERAMIC

|
15| CB1| –| 1| EEV-FK2A101| PANASONIC| 100UF| CAP; SMT (CASE_J16); 100UF; 20%; 100V;

ALUMINUM-ELECTROLYTIC

|
16| D1| –| 1| SML-P11UTT86| ROHM| SML-P11UTT86| DIODE; LED; SMT; PIV=1.8V; IF=0.02A ;|
17| D2| –| 1| SMF5.0A| MICRO COMMERCIAL

COMPONENTS

| 5V| DIODE; TVS; SMT (SOD-123FL); VRM=5V;

IF=21.7A

|
18| DS1| –| 1| SSL-LX3044GD-12V| LUMEX OPTO COMPONENTS INC| LX3044GD-12V| GREEN LIGHT EMITTING DIODE|

19

| ****

J1

| ****

–

| ****

1

| ****

1727010

| PHOENIX CONTACT| 1727010| CONNECTOR; FEMALE; THROUGH HOLE; GREEN TERMINAL BLOCK; RIGHT ANGLE;

2PINS

|

20

| ****

J2, J8

| ****

–

| ****

2

| ****

PBC06SFCN

| SULLINS ELECTRONICS CORP.| PBC06SFCN| CONNECTOR; MALE; THROUGH HOLE;

.1IN CONTACT CENTER; BREAKAWAY HEADER; STRAIGHT; 6PINS

|

21

| ****

J3

| ****

–

| ****

1

| ****

ZX62RD-AB-5P8(30)

| HIROSE ELECTRIC CO LTD.| ZX62RD-AB-5P8(30)| CONNECTOR; MALE; THROUGH HOLE; MICRO-USB CONNECTOR MEETING REQUIREMENTS OF USB 2.0 STANDARD;

RIGHT ANGLE; 5PINS

BREAKAWAY; STRAIGHT; 2PINS

|
23| J5| –| 1| PJ-102B| CUI INC.| PJ-102B| CONNECTOR; MALE; THROUGH HOLE; DC

POWER JACK; RIGHT ANGLE; 3PIN

|

24

| ****

J6

| ****

–

| ****

1

| ****

OSTVN04A150

| ON-SHORE TECHNOLOGY INC| OSTVN04A150| CONNECTOR; TERMINAL BLOCK;

FEMALE; THROUGH HOLE; STRAIGHT; 4PINS

|

25

| ****

J7

| ****

–

| ****

1

| ****

PBC04SAAN

| SULLINS ELECTRONICS CORP.| PBC04SAAN| CONNECTOR; MALE; THROUGH HOLE;

BREAKAWAY; STRAIGHT; 4PINS; -65 DEGC TO +125 DEGC

|
26| J11, J12| –| 2| PBC10DAAN| SULLINS ELECTRONICS CORP| PBC10DAAN| CONNECTOR; MALE; THROUGH HOLE;

BREAKAWAY; STRAIGHT; 20PINS

|

27

| ****

J13

| ****

–

| ****

1

| ****

PEC03DAAN

| ****

SULLINS ELECTRONICS CORP.

| ****

PEC03DAAN

| CONNECTOR; MALE; THROUGH HOLE;

BREAKAWAY; STRAIGHT THROUGH; 6PINS; -65 DEGC TO +125 DEGC

|
28| R1| –| 1| CRCW04021K40FK;

RC0402FR-071K4L

| VISHAY DALE; YAGEO PHICOMP| 1.4K| RES; SMT (0402); 1.4K; 1%; +/-

100PPM/DEGC; 0.0630W

|

29

| ****

R2, R7, R12, R14, R15, R20, R21

| ****

–

| ****

7

| CRCW06030000ZS; MCR03EZPJ000; ERJ-3GEY0R00;

CR0603AJ/-000ELF

| VISHAY;ROHM SEMICONDUCTOR; PANASONIC;BOURNS| 0| ****

RES; SMT (0603); 0; JUMPER; JUMPER; 0.1000W

|
30| R4, R18| –| 2| CRCW06034K70FK| VISHAY DALE| 4.7K| RES; SMT (0603); 4.7K; 1%; +/-

100PPM/DEGC; 0.1000W

|
ITEM| REF_DES| DNI/DNP| QTY| MFG PART #| MANUFACTURER| VALUE| DESCRIPTION| COMMENTS
---|---|---|---|---|---|---|---|---
31| R8, R9, R24-R26, R29,

R30, R70-R74

| –| 12| ERJ-2GE0R00| PANASONIC| 0| RES; SMT (0402); 0; JUMPER; JUMPER;

0.1000W

|

32

| ****

R10

| ****

–

| ****

1

| CRCW0603100KFK; RC0603FR-07100KL; RC0603FR-13100KL; ERJ-3EKF1003;

AC0603FR-07100KL

| ****

VISHAY DALE;YAGEO;YAGEO; PANASONIC;YAGEO

| ****

100K

| ****

RES; SMT (0603); 100K; 1%; +/- 100PPM/DEGC; 0.1000W

|
33| R11| –| 1| ERJ-3EKF6200| PANASONIC| 620| RES; SMT (0603); 620; 1%; +/-

100PPM/DEGC; 0.1000W

|

34

| ****

R13, R19

| ****

–

| ****

2

| CRCW06031K00FK; ERJ-3EKF1001; CR0603AFX-1001ELF;

RMCF0603FT1K00

| ****

VISHAY; PANASONIC; BOURNS; STACKPOLE ELECTRONICS INC.

| ****

1K

| ****

RES; SMT (0603); 1K; 1%; +/- 100PPM/DEGC; 0.1000W

|
35| R17| –| 1| CSR1206FTR500| STACKPOLE ELECTRONICS INC.| 0.5| RES; SMT (1206); 0.5; 1%; +/-

100PPM/DEGC; 0.5000W

|
36| R22, R23| –| 2| CRCW12060000ZS| VISHAY DALE| 0| RES; SMT (1206); 0; JUMPER; JUMPER;

0.2500W

|
37| R27, R28, R31-R69,

R75, R76

| –| 43| RC0402FR-0710KL;

CR0402-FX-1002GLF

| YAGEO;BOURNS| 10K| RES; SMT (0402); 10K; 1%; +/-

100PPM/DEGC; 0.0630W

|
38| RISENA, RISENB| –| 2| ERA-2AEB3741X| PANASONIC| 3.74K| RES; SMT (0402); 3.74K; 0.10%; +/-

25PPM/DEGC; 0.0630W

|
39| ROFF| –| 1| ERJ-2RKF3002| PANASONIC| 30K| RES; SMT (0402); 30K; 1%; +/-

100PPM/DEGC; 0.1000W

|
40| RREF| –| 1| ERJ-2RKF1802| PANASONIC| 18K| RES; SMT (0402); 18K; 1%; +/-

100PPM/DEGC; 0.1000W

|

41

| ****

SW1

| ****

–

| ****

1

| ****

NK236

| ****

APEM

| ****

NK236

| SWITCH; SPDT; THROUGH HOLE; 12V; 0.5A; NK SERIES; RCOIL= OHM;

RINSULATION= OHM; APEM

|

42

| ****

SW2

| ****

–

| ****

1

| ****

PTS645SK50SMTR92LFS

| ****

C&K COMPONENTS

| ****

PTS645SK50SMTR92LFS

| SWITCH; SPST; SMT; STRAIGHT; 12V;

0.05A; TACT SWITCHES; RCOIL=0.1 OHM; RINSULATION=100G OHM

|

43

| ****

TP1, TP5, TP8

| ****

–

| ****

3

| ****

5010

| ****

KEYSTONE

| ****

N/A

| TEST POINT; PIN DIA=0.125IN; TOTAL LENGTH=0.445IN; BOARD HOLE=0.063IN; RED; PHOSPHOR BRONZE WIRE SIL;|

44

| ****

TP2, TP6, TP7, TP22- TP24

| ****

–

| ****

6

| ****

5011

| ****

KEYSTONE

| ****

N/A

| TEST POINT; PIN DIA=0.125IN; TOTAL LENGTH=0.445IN; BOARD HOLE=0.063IN; BLACK; PHOSPHOR BRONZE WIRE

SILVER PLATE FINISH;

|

45

| ****

TP3, TP4, TP9,

TP11-TP21, TP25, TP26

| ****

–

| ****

16

| ****

5012

| ****

KEYSTONE

| ****

N/A

| TEST POINT; PIN DIA=0.125IN; TOTAL LENGTH=0.445IN; BOARD HOLE=0.063IN; WHITE; PHOSPHOR BRONZE WIRE

SILVER PLATE FINISH;

|

46

| ****

U1

| ****

–

| ****

1

| ****

MAX22210_TQFN

| ****

ANALOG DEVICES

| ****

MAX22210_TQFN

| EVKIT PART – IC; MAX22210; 36V; 3.8A STEPPER MOTOR DRIVER WITH INTEGRATED CURRENT SENSE AND 128 STEPS INDEXER; PACKAGE OUTLINE DRAWING: 21-0140; PACKAGE LAND PATTERN: 90-0013; TQFN32-EP|

47

| ****

U2

| ****

–

| ****

1

| ****

MAX6765TTSD2+

| ****

ANALOG DEVICES

| ****

MAX6765TTSD2+

| IC; VREG; AUTOMOTIVE MICROPOWER

LINEAR REGULATOR WITH SUPERVISOR; TDFN6-EP

|

48

| ****

U3

| ****

–

| ****

1

| ****

DSPIC33CH512MP508T-I/PT

| ****

MICROCHIP

| ****

DSPIC33CH512MP508T- I/PT

| IC; CTRL; 16-BIT DIGITAL SIGNAL CONTROLLERS WITH HIGH-RESOLUTION PWM AND CAN FLEXIBLE DATA RATE;

TQFP80-EP

|

49

| ****

U4

| ****

–

| ****

1

| ****

MCP2221A-I/ST

| ****

MICROCHIP

| ****

MCP2221A-I/ST

| IC; CONV; USB 2.0 TO I2C/UART

PROTOCOL CONVERTER WITH GPIO; TSSOP14

|

50

| ****

U5

| ****

–

| ****

1

| ****

SI8422AB-D-IS

| ****

SILICON LABORATORIES

| ****

SI8422AB-D-IS

| IC; DISO; LOW-POWER; SINGLE AND

DUAL-CHANNEL DIGITAL ISOLATORS; NSOIC8

|
51| U6| –| 1| MIC5528-3.3YMT| MICROCHIP| MIC5528-3.3YMT| IC; VREG; HIGH PERFORMANCE 500 MA

LDO; TDFN6-EP

|
52| Y1| –| 1| DSC6011JI1B-008.0000| MICROCHIP| DSC6011JI1B-008.0000| OSCILLATOR; SMT 2.5X2.0; 8MHZ; +/-

50PPM;

|
53| PCB| –| 1| MAX22210| ANALOG DEVICES| PCB| PCB:MAX22210| –
54| C5| DNP| 0| GRM155R61C104KA88| MURATA| 0.1UF| CAP; SMT (0402); 0.1UF; 10%; 16V; X5R;

CERAMIC

| DNI

55

| ****

C6, C7

| ****

DNP

| ****

0

| C0402X7R500-222KNE;

GRM155R71H222KA01; C1005X7R1H222K050BA

| ****

VENKEL LTD.;MURATA;TDK

| ****

2200PF

| CAP; SMT (0402); 2200PF; 10%; 50V; X7R; CERAMIC| ****

DNI

56| C44| DNP| 0| C0603C473K3RAC;

GRM188R71E473KA01

| KEMET;MURATA| 0.047UF| CAP; SMT (0603); 0.047UF; 10%; 25V; X7R;

CERAMIC;

|

57

| ****

R3, R5

| ****

DNP

| ****

0

| CRCW06030000ZS; MCR03EZPJ000; ERJ-3GEY0R00;

CR0603AJ/-000ELF

| ****

VISHAY;ROHM SEMICONDUCTOR; PANASONIC;BOURNS

| ****

0

| ****

RES; SMT (0603); 0; JUMPER; JUMPER; 0.1000W

| ****

DNI

58

| ****

R6

| ****

DNP

| ****

0

| CRCW0603100KFK; RC0603FR-07100KL; RC0603FR-13100KL; ERJ-3EKF1003;

AC0603FR-07100KL

| ****

VISHAY DALE;YAGEO;YAGEO; PANASONIC;YAGEO

| ****

100K

| ****

RES; SMT (0603); 100K; 1%; +/- 100PPM/DEGC; 0.1000W

|
59| R16| DNP| 0| CRCW12060000ZS| VISHAY DALE| 0| RES; SMT (1206); 0; JUMPER; JUMPER;

0.2500W

|
TOTAL| | | 173| | | | |

MAX22210 EV Kit Schematic

ANALOG-DEVICES-MAX22210-Evaluation-Kit-fig-9

MAX22210 EV Kit PCB Layout

ANALOG-DEVICES-MAX22210-Evaluation-Kit-fig-12

Revision History

REVISION NUMBER| REVISION DATE| DESCRIPTION| PAGES CHANGED
---|---|---|---
0| 8/23| Initial release| —

Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications are subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners.

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