KS0341A Keyestudio REV4 (Black) Main Control Board: Difference between revisions

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[[image:0341.jpg|thumb|500px|right|Keyestudio UNO Compatible Board Advanced ]]
[[image:0341.jpg|thumb|500px|right|Keyestudio REV4 Compatible Board Advanced ]]


<br>
<br>
==Introduction==
==Introduction==
The keyestudio UNO compatible board Advanced is a microcontroller board based on the ATmega328P [http://www.atmel.com/dyn/resources/prod_documents/doc8161.pdf (datasheet)], fully compatible with [http://wiki.keyestudio.com/index.php/Ks0001_keyestudio_UNO_R3_BOARD keyestudio UNO R3 board] and ARDUINO UNO REV3. <br>
The keyestudio REV4 compatible board Advanced is a microcontroller board based on the ATmega328P [http://www.atmel.com/dyn/resources/prod_documents/doc8161.pdf (datasheet)], fully compatible with [http://wiki.keyestudio.com/index.php/Ks0001_keyestudio_UNO_R3_BOARD keyestudio REV3 board] and ARDUINO UNO. <br>
It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz quartz crystal, a USB connection, a power jack, 2 ICSP headers and a reset button. <br>
It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz quartz crystal, a USB connection, a power jack, 2 ICSP headers and a reset button. <br>
Note that the two ICSP headers are separately used to program the firmware to ATMEGA16U2-MU and ATMEGA328P-PU, but generally the two chips have been programmed well.<br>
Note that the two ICSP headers are separately used to program the firmware to ATMEGA16U2-MU and ATMEGA328P-PU, but generally the two chips have been programmed well.<br>
It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it via an external DC power jack (DC 7-12V) or via female headers Vin/ GND(DC 7-12V) to get started.<br>
It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it via an external DC power jack (DC 7-12V) or via female headers Vin/ GND(DC 7-12V) to get started.<br>


<span style=color:red> '''Note:''' the most important difference between this keyestudio UNO Advanced board and keyestudio UNO R3 board is the voltage regulator chip used in the board. <br>
<span style=color:red> '''Note:''' the most important difference between this keyestudio REV3 Advanced board and keyestudio REV4 board is the voltage regulator chip used in the board. <br>
The voltage regulator chip used in keyestudio UNO R3 board is NSP1117. When connect an external power, output 5V, the drive current is 1A. However, keyestudio UNO Advanced board features the voltage-regulator chip MP2307DN. When connect the external power, output 5V, the drive current can be 2A. </span><br>
The voltage regulator chip used in keyestudio REV4 board is NSP1117. When connect an external power, output 5V, the drive current is 1A. However, keyestudio REV4 Advanced board features the voltage-regulator chip MP2307DN. When connect the external power, output 5V, the drive current can be 2A. </span><br>


<br>
<br>
The UNO is the best board to get started with electronics and coding. If this is your first experience tinkering with the platform, the UNO is the most robust board you can start playing with.
The REV4 is the best board to get started with electronics and coding. If this is your first experience tinkering with the platform, the REV4 is the most robust board you can start playing with.
<br>
<br>
{| class="wikitable" cellpadding="1" cellspacing="1"
{| class="wikitable" cellpadding="1" cellspacing="1"
|-
|-
! scope="row" |  
! scope="row" |  
! scope="row" | keyestudio UNO compatible board Advanced
! scope="row" | Keyestudio REV4 (Black) Main Control Board
! scope="row" | keyestudio UNO R3 board
! scope="row" |Keyestudio REV3 (Black)Main Control Board
|-
|-
! scope="row" | voltage-regulator chip
! scope="row" | voltage-regulator chip
Line 40: Line 40:


<br>
<br>
<span style=color:brown><big>'''keyestudio UNO R3 board:''' </span></big>  
<span style=color:brown><big>'''keyestudio REV3 board:''' </span></big>  
<br>[[Image:Ks0001.png|700px|frameless]]<br>
<br>[[Image:REV3.jpg|700px|frameless]]<br>


<br>
<br>
<span style=color:brown><big>'''keyestudio UNO compatible board Advanced:''' </span></big>
<span style=color:brown><big>'''keyestudio REV4 compatible board Advanced:''' </span></big>
<br>[[Image:Ks0341.png|700px|frameless]]<br>
<br>[[Image:REV4.jpg|700px|frameless]]<br>


<br>
<br>
Line 97: Line 97:
* '''Dimensions:''' 75mm x 54mm x 15mm
* '''Dimensions:''' 75mm x 54mm x 15mm
* '''Weight:''' 27g
* '''Weight:''' 27g
[[Image:KS0341-1.jpg|1000px|frameless]]<br>
[[Image:KS0341-2.jpg|700px|]]<br>


<br>
<br>
==Element and Interface==
==Element and Interface==
Here is an explanation of what every element and interface of the board does:
Here is an explanation of what every element and interface of the board does:
Line 119: Line 120:
| align="center" | [[Image:KS0001 5-3.png|500px|frameless]]
| align="center" | [[Image:KS0001 5-3.png|500px|frameless]]
| align="light" | '''Digital I/O'''
| align="light" | '''Digital I/O'''
Arduino UNO has 14 digital input/output pins (of which 6 can be used as PWM outputs). These pins can be configured as digital input pin to read the logic value (0 or 1). Or used as digital output pin to drive different modules like LED, relay, etc. The pin labeled “〜” can be used to generate PWM.  
Arduino REV4 has 14 digital input/output pins (of which 6 can be used as PWM outputs). These pins can be configured as digital input pin to read the logic value (0 or 1). Or used as digital output pin to drive different modules like LED, relay, etc. The pin labeled “〜” can be used to generate PWM.  
|-
|-


Line 223: Line 224:
| align="center" | [[Image:KS0001 5-23.png|500px|frameless]]
| align="center" | [[Image:KS0001 5-23.png|500px|frameless]]
| align="light" | '''Analog Pins'''
| align="light" | '''Analog Pins'''
Arduino UNO board has 6 analog inputs, labeled A0 through A5. <br>
Arduino REV4 board has 6 analog inputs, labeled A0 through A5. <br>
These pins can read the signal from analog sensors (such as humidity sensor or temperature sensor), and convert it into the digital value that can read by microcontrollers)
These pins can read the signal from analog sensors (such as humidity sensor or temperature sensor), and convert it into the digital value that can read by microcontrollers)
Can also used as digital pins, A0=D14, A1=D15, A2=D16, A3=D17, A4=D18, A5=D19.  
Can also used as digital pins, A0=D14, A1=D15, A2=D16, A3=D17, A4=D18, A5=D19.  
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<br>
<br>
==Tips==
==Tips==
* Automatic (Software) Reset:
* Automatic (Software) Reset:
Rather than requiring a physical press of the reset button before an upload, the Arduino Uno board is designed in a way that allows it to be reset by software running on a connected computer.  
Rather than requiring a physical press of the reset button before an upload, the Arduino REV4 board is designed in a way that allows it to be reset by software running on a connected computer.  
* The Uno board contains a trace that can be cut to disable the auto-reset. The pads on either side of the trace can be soldered together to re-enable it. It's labeled "RESET-EN". You may also be able to disable the auto-reset by connecting a 110 ohm resistor from 5V to the reset line; see [http://forum.arduino.cc/index.php/topic,22974.0.html this forum thread] for details.
* The REV4 board contains a trace that can be cut to disable the auto-reset. The pads on either side of the trace can be soldered together to re-enable it. It's labeled "RESET-EN". You may also be able to disable the auto-reset by connecting a 110 ohm resistor from 5V to the reset line; see [http://forum.arduino.cc/index.php/topic,22974.0.html this forum thread] for details.
 
<br>
 
 
 
 
==Resources Download==
* You might also want to look at:<br>
[https://www.arduino.cc/en/Tutorial/HomePage the examples] for using various sensors and actuators;<br>
[https://www.arduino.cc/reference/en/ the reference] for the Arduino language;<br>
* You can download the datasheet from the link:<br>
https://1drv.ms/b/s!ArhgRvK6-RyJhGLtZMjI-8SWXl8V?e=895eSt <br>
* Software Download:<br>
https://drive.google.com/open?id=12D-JkXdNm03Qt4dlPQr3RP6OmgXqpvHc
 


<br>
<br>
Line 256: Line 273:
<br>
<br>
===Step1 | Download the Arduino environment (IDE)===
===Step1 | Download the Arduino environment (IDE)===
When you get the UNO development board, first you should install the Arduino software and driver. <br>
When you get the REV4 development board, first you should install the Arduino software and driver. <br>
We usually use the Windows software Arduino 1.5.6 version. You can download it from the link below: <br>
We usually use the Windows software Arduino 1.5.6 version. You can download it from the link below: <br>
https://www.arduino.cc/en/Main/OldSoftwareReleases#1.5.x<br>
https://www.arduino.cc/en/Main/OldSoftwareReleases#1.5.x<br>
Line 298: Line 315:
<br>
<br>
====Installing Driver====
====Installing Driver====
Next, we will introduce the driver installation of UNO R3 development board. The driver installation may have slight differences in different computer systems. So in the following let’s move on to the driver installation in the WIN 7 system. <br>
Next, we will introduce the driver installation of REV4 development board. The driver installation may have slight differences in different computer systems. So in the following let’s move on to the driver installation in the WIN 7 system. <br>
The Arduino folder contains both the Arduino program itself and the drivers that allow the Arduino to be connected to your computer by a USB cable. Before we launch the Arduino software, you are going to install the USB drivers.<br>
The Arduino folder contains both the Arduino program itself and the drivers that allow the Arduino to be connected to your computer by a USB cable. Before we launch the Arduino software, you are going to install the USB drivers.<br>
<br>[[Image:KS0001-1.jpg|600px|frameless]]<br>
<br>[[Image:KS0001-1.jpg|600px|frameless]]<br>
Plug one end of your USB cable into the Arduino and the other into a USB socket on your computer.
Plug one end of your USB cable into the Arduino and the other into a USB socket on your computer.
When you connect UNO board to your computer at the first time, right click the icon of your “Computer” —>for “Properties”—> click the “Device manager”, under “Other Devices”, you should see an icon for “Unknown device” with a little yellow warning triangle next to it. This is your Arduino.<br>
When you connect REV4 board to your computer at the first time, right click the icon of your “Computer” —>for “Properties”—> click the “Device manager”, under “Other Devices”, you should see an icon for “Unknown device” with a little yellow warning triangle next to it. This is your Arduino.<br>
<br>[[Image:Driver 1.png|600px|frameless]]<br>
<br>[[Image:Driver 1.png|600px|frameless]]<br>
Then right-click on the device and select the top menu option (Update Driver Software...) shown as the figure below..   
Then right-click on the device and select the top menu option (Update Driver Software...) shown as the figure below..   
Line 356: Line 373:
<br>
<br>
===Step2| Connect the board===
===Step2| Connect the board===
Connect the UNO board to your computer using the USB cable. The green power LED should go on.
Connect the REV4 board to your computer using the USB cable. The green power LED should go on.
<br>[[Image:KS0341-2.jpg|600px|frameless]]<br>
<br>[[File:KS0341 sy.jpg|600px|frameless]]<br>


<br>
<br>
===Step3| Select the Arduino Board ===
===Step3| Select the Arduino Board ===
Open the Arduino IDE, you’ll need to click the “Tools”, then select the Board that corresponds to your Arduino.
Open the Arduino IDE, you’ll need to click the “Tools”, then select the Board that corresponds to your Arduino.
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<br>
<br>
== Package Included ==
== Package Included ==
* keyestudio UNO Advanced board * 1pcs
* keyestudio REV4 Advanced board * 1pcs
* USB cable * 1pcs
* USB cable * 1pcs
<br>[[Image:KS0341-3.jpg|600px|frameless]]<br>
<br>[[Image:KS0341 单 (2).jpg|600px|frameless]]<br>




<br>
<br>
==Other Resources==
* You might also want to look at:<br>
[https://www.arduino.cc/en/Tutorial/HomePage the examples] for using various sensors and actuators;<br>
[https://www.arduino.cc/reference/en/ the reference] for the Arduino language;<br>
* You can download the datasheet from the link:<br>
https://drive.google.com/open?id=1t6mqdd4EUA4kvwIJrRG-VHU2H9iZEJHF <br>
* Software Download:<br>
https://drive.google.com/open?id=12D-JkXdNm03Qt4dlPQr3RP6OmgXqpvHc


<br>
==Troubleshooting==
==Troubleshooting==
If you have problems, please see the [https://www.arduino.cc/en/Guide/Troubleshooting troubleshooting suggestions].
If you have problems, please see the [https://www.arduino.cc/en/Guide/Troubleshooting troubleshooting suggestions].


==Resources ==
'''Download the PDF:'''<br>


https://fs.keyestudio.com/KS0341A


==Get One Now==
==Get One Now==

Latest revision as of 13:56, 30 April 2021

Keyestudio REV4 Compatible Board Advanced


Introduction

The keyestudio REV4 compatible board Advanced is a microcontroller board based on the ATmega328P (datasheet), fully compatible with keyestudio REV3 board and ARDUINO UNO.
It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz quartz crystal, a USB connection, a power jack, 2 ICSP headers and a reset button.
Note that the two ICSP headers are separately used to program the firmware to ATMEGA16U2-MU and ATMEGA328P-PU, but generally the two chips have been programmed well.
It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it via an external DC power jack (DC 7-12V) or via female headers Vin/ GND(DC 7-12V) to get started.

Note: the most important difference between this keyestudio REV3 Advanced board and keyestudio REV4 board is the voltage regulator chip used in the board.
The voltage regulator chip used in keyestudio REV4 board is NSP1117. When connect an external power, output 5V, the drive current is 1A. However, keyestudio REV4 Advanced board features the voltage-regulator chip MP2307DN. When connect the external power, output 5V, the drive current can be 2A.


The REV4 is the best board to get started with electronics and coding. If this is your first experience tinkering with the platform, the REV4 is the most robust board you can start playing with.

Keyestudio REV4 (Black) Main Control Board Keyestudio REV3 (Black)Main Control Board
voltage-regulator chip MP2307DN NSP1117
Power Output 5V 5V
Drive Current(external power) 2A 1A
Drive Current(USB power) 0.5A 0.5A


keyestudio REV3 board:
REV3.jpg


keyestudio REV4 compatible board Advanced:
REV4.jpg


TECH SPECS

Microcontroller ATmega328P-PU
Operating Voltage 5V
Input Voltage (recommended) DC7-12V
Digital I/O Pins 14 (D0-D13)(of which 6 provide PWM output)
PWM Digital I/O Pins 6 (D3, D5, D6, D9, D10, D11)
Analog Input Pins 6 (A0-A5)
DC Current per I/O Pin 20 mA
DC Current for 3.3V Pin 50 mA
Flash Memory 32 KB (ATmega328) of which 0.5 KB used by bootloader
SRAM 2 KB (ATmega328P-PU)
EEPROM 1 KB (ATmega328P-PU)
Clock Speed 16 MHz
LED_BUILTIN D13


Details

  • Dimensions: 75mm x 54mm x 15mm
  • Weight: 27g

KS0341-2.jpg


Element and Interface

Here is an explanation of what every element and interface of the board does:
KS0341 引脚标图.jpg

KS0001 5-1.png ICSP (In-Circuit Serial Programming) Header

In most case, ICSP is the AVR,an Arduino micro-program header consisting of MOSI, MISO, SCK, RESET, VCC, and GND. It is often called the SPI (serial peripheral interface) and can be considered an "extension" of the output. In fact, slave the output devices under the SPI bus host.
When connecting to PC, program the firmware to ATMEGA328P-PU.

KS0001 5-2.png Power LED Indicator

Powering the Arduino, LED on means that your circuit board is correctly powered on. If LED is off, connection is wrong.

KS0001 5-3.png Digital I/O

Arduino REV4 has 14 digital input/output pins (of which 6 can be used as PWM outputs). These pins can be configured as digital input pin to read the logic value (0 or 1). Or used as digital output pin to drive different modules like LED, relay, etc. The pin labeled “〜” can be used to generate PWM.

KS0001 5-4.png GND ( Ground pin headers)

Used for circuit ground

KS0001 5-5.png AREF

Reference voltage (0-5V) for analog inputs. Used with analogReference().

KS0001 5-6.png SDA

IIC communication pin

KS0001 5-7.png SCL

IIC communication pin

KS0001 5-8.png ICSP (In-Circuit Serial Programming) Header

In most case, ICSP is the AVR,an Arduino micro-program header consisting of MOSI, MISO, SCK, RESET, VCC, and GND. Connected to ATMEGA 16U2-MU. When connecting to PC, program the firmware to ATMEGA 16U2-MU.

KS0001 5-9.png RESET Button

You can reset your Arduino board, for example, start the program from the initial status. You can use the RESET button.

KS0001 5-10.png D13 LED

There is a built-in LED driven by digital pin 13. When the pin is HIGH value, the LED is on, when the pin is LOW, it's off.

KS0001 5-11.png USB Connection

Arduino board can be powered via USB connector.
All you needed to do is connecting the USB port to PC using a USB cable.

KS0001 5-12.png ATMEGA 16U2-MU

USB to serial chip, can convert the USB signal into serial port signal.

KS0001 5-13.png TX LED

Onboard you can find the label: TX (transmit)
When Arduino board communicates via serial port, send the message, TX led flashes.

KS0001 5-14.png RX LED

Onboard you can find the label: RX(receive )
When Arduino board communicates via serial port, receive the message, RX led flashes.

KS0001 5-15.png Crystal Oscillator

How does Arduino calculate time? by using a crystal oscillator.
The number printed on the top of the Arduino crystal is 16.000H9H. It tells us that the frequency is 16,000,000 Hertz or 16MHz.

KS0001 5-16.png Voltage Regulator

Convert an external input DC7-12V voltage into DC 5V, then switch DC 5V to the processor and other components. Output DC 5V, the drive current is 2A.

KS0001 5-17.png DC Power Jack

Arduino board can be supplied with an external power DC7-12V from the DC power jack.

KS0001 5-18.png IOREF

Used to configure the operating voltage of microcontrollers. Use it less.

KS0001 5-19.png RESET Header

Connect an external button to reset the board. The function is the same as reset button (labeled 9)

KS0001 5-20.png Power Pin 3V3

A 3.3 volt supply generated by the on-board regulator. Maximum current draw is 50 mA.

KS0001 5-21.png Power Pin 5V

Provides 5V output voltage

KS0001 5-22.png Vin

You can supply an external power input DC7-12V through this pin to Arduino board.

KS0001 5-23.png Analog Pins

Arduino REV4 board has 6 analog inputs, labeled A0 through A5.
These pins can read the signal from analog sensors (such as humidity sensor or temperature sensor), and convert it into the digital value that can read by microcontrollers) Can also used as digital pins, A0=D14, A1=D15, A2=D16, A3=D17, A4=D18, A5=D19.

KS0001 5-24.png Microcontroller

Each Arduino board has its own microcontroller. You can regard it as the brain of your board.
The main IC (integrated circuit) on the Arduino is slightly different from the panel pair. Microcontrollers are usually from ATMEL. Before you load a new program on the Arduino IDE, you must know what IC is on your board. This information can be checked at the top of IC.


Specialized Functions of Some Pins

  • Serial communication: Digital pins 0 (RX) and 1 (TX).
  • PWM Interfaces (Pulse-Width Modulation): D3, D5, D6, D9, D10, D11
  • External Interrupts: D2 (interrupt 0) and D3 (interrupt 1). These pins can be configured to trigger an interrupt on a low value, a rising or falling edge, or a change in value.
  • SPI communication: D10 (SS), D11 (MOSI), D12 (MISO), D13 (SCK). These pins support SPI communication using the SPI library.
  • IIC communication: A4 (SDA); A5(SCL)

KS0341 引脚.jpg



Tips

  • Automatic (Software) Reset:

Rather than requiring a physical press of the reset button before an upload, the Arduino REV4 board is designed in a way that allows it to be reset by software running on a connected computer.

  • The REV4 board contains a trace that can be cut to disable the auto-reset. The pads on either side of the trace can be soldered together to re-enable it. It's labeled "RESET-EN". You may also be able to disable the auto-reset by connecting a 110 ohm resistor from 5V to the reset line; see this forum thread for details.




Resources Download

  • You might also want to look at:

the examples for using various sensors and actuators;
the reference for the Arduino language;

  • You can download the datasheet from the link:

https://1drv.ms/b/s!ArhgRvK6-RyJhGLtZMjI-8SWXl8V?e=895eSt

  • Software Download:

https://drive.google.com/open?id=12D-JkXdNm03Qt4dlPQr3RP6OmgXqpvHc



Detailed Use with ARDUINO Software as follows


Step1 | Download the Arduino environment (IDE)

When you get the REV4 development board, first you should install the Arduino software and driver.
We usually use the Windows software Arduino 1.5.6 version. You can download it from the link below:
https://www.arduino.cc/en/Main/OldSoftwareReleases#1.5.x
Or you can browse the ARDUINO website to download the latest version from this link, https://www.arduino.cc, pop up the following interface.
KS0313-1.png

Then click the SOFTWARE on the browse bar, you will have two options ONLINE TOOLS and DOWNLOADS.
KS0313-2.png

Click DOWNLOADS, it will appear the latest software version of ARDUINO 1.8.5 shown as below.
KS0313-3.png

In this software page, on the right side you can see the version of development software for different operating systems. ARDUINO has a powerful compatibility. You should download the software that is compatible with the operating system of your computer.
We will take WINDOWS system as an example here. There are also two options under Windows system, one is installed version, the other is non-installed version. For simple installed version, first click Windows Installer, you will get the following page.

KS0313-4.png

KS0313-5.png

This way you just need to click JUST DOWNLOAD, then click the downloaded file to install it.
For non-installed version, first click Windows ZIP file, you will also get the pop-up interface as the above figure.
Click JUST DOWNLOAD, and when the ZIP file is downloaded well to your computer, you can directly unzip the file and click the icon of ARDUINO software to start it.


Installing Arduino (Windows)

Install Arduino with the exe. Installation package downloaded well.
thumb

Click“I Agree”to see the following interface.
thumb

Click “Next”. Pop up the interface below.
thumb

You can press Browse… to choose an installation path or directly type in the directory you want.
Then click “Install” to initiate installation.
thumb

Wait for the installing process, if appear the interface of Window Security, just continue to click Install to finish the installation.
thumb


Installing Driver

Next, we will introduce the driver installation of REV4 development board. The driver installation may have slight differences in different computer systems. So in the following let’s move on to the driver installation in the WIN 7 system.
The Arduino folder contains both the Arduino program itself and the drivers that allow the Arduino to be connected to your computer by a USB cable. Before we launch the Arduino software, you are going to install the USB drivers.

KS0001-1.jpg
Plug one end of your USB cable into the Arduino and the other into a USB socket on your computer. When you connect REV4 board to your computer at the first time, right click the icon of your “Computer” —>for “Properties”—> click the “Device manager”, under “Other Devices”, you should see an icon for “Unknown device” with a little yellow warning triangle next to it. This is your Arduino.

Driver 1.png
Then right-click on the device and select the top menu option (Update Driver Software...) shown as the figure below..
Driver 2.png

It will then be prompted to either “Search Automatically for updated driversoftware” or “Browse my computer for driver software”. Shown as below. In this page, select “Browse my computer for driver software”.
Driver 3.png

After that, select the option to browseand navigate to the “drivers” folder of Arduino installation.
KS0286-4.png

Click “Next” and you may get a security warning, if so, allow the software to be installed. Shown as below.
Driver 5.png

Once the software has been installed, you will get a confirmation message. Installation completed, click “Close”.
Driver 6.png

Up to now, the driver is installed well. Then you can right click “Computer” —>“Properties”—>“Device manager”, you should see the device as the figure shown below.
Driver 7.png


Introduction for Arduino IDE Toolbar

Double-click the icon of Arduino software downloaded well, you will get the interface shown below.
Ks0313图片1.png
(Note: if the Arduino software loads in the wrong language, you can change it in the preferences dialog. See the environment page for details.)
717.png

The functions of each button on the Toolbar are listed below:
IDE.png

IDE 1.png Verify/Compile Check the code for errors
IDE 2.png Upload Upload the current Sketch to the Arduino
IDE 3.png New Create a new blank Sketch
IDE 4.png Open Show a list of Sketches
IDE 5.png Save Save the current Sketch
IDE 6.png Serial Monitor Display the serial data being sent from the Arduino


Step2| Connect the board

Connect the REV4 board to your computer using the USB cable. The green power LED should go on.
KS0341 sy.jpg


Step3| Select the Arduino Board

Open the Arduino IDE, you’ll need to click the “Tools”, then select the Board that corresponds to your Arduino.
Step3.jpg


Step4| Select the Serial Port

Select the serial device of the Arduino board from the Tools | Serial Port menu. This is likely to be COM3 or higher (COM1and COM2 are usually reserved for hardware serial ports). To find out, you can disconnect your Arduino board and re-open the menu; the entry that disappears should be the Arduino board. Reconnect the board and select that serial port.
Step4.jpg

Note: to avoid errors, the COM Port should keep the same as the Ports shown on Device Manager.
Step4-1.jpg

Step4-2.jpg


Step5| Upload the Program

Below is an example program for displaying the Hello World!
Copy and paste the code to the Arduino environment IDE.

int val; 
int ledpin=13; 
void setup()
{
Serial.begin(9600); 
pinMode(ledpin,OUTPUT);
}
void loop()
{
val=Serial.read();
if(val=='R')
{
digitalWrite(ledpin,HIGH);
delay(500);
digitalWrite(ledpin,LOW);
delay(500);
Serial.println("Hello World!");
}
}

Then click verify button to check the errors. If compiling successfully, the message "Done compiling." will appear in the status bar.
Step5.png

After that, click the “Upload” button to upload the code. If the upload is successful, the message "Done uploading." will appear in the status bar. (Note: If you have an Arduino Mini, NG, or other board, you'll need to physically present the reset button on the board immediately before pressing the upload button.)
Step5-1.png


Step6| Open the Serial Monitor

After that, click the serial monitor button to open the serial monitor.
UNO monitor.png
Then set the baud rate as 9600, enter an “R” and click Send, you should see the RX led on the board blink once, and then D13 led blink once, finally "Hello World!" is showed on the monitor, the TX led blink once. Congrats!
Ks0248 monitor 2.png



Package Included

  • keyestudio REV4 Advanced board * 1pcs
  • USB cable * 1pcs


KS0341 单 (2).jpg



Troubleshooting

If you have problems, please see the troubleshooting suggestions.

Resources

Download the PDF:

https://fs.keyestudio.com/KS0341A

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