MIKROE-551 mikroElektronika, MIKROE-551 Datasheet

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MIKROE-551

Manufacturer Part Number
MIKROE-551
Description
Development Boards & Kits - AVR AVRPLC16 V6
Manufacturer
mikroElektronika
Datasheet

Specifications of MIKROE-551

Rohs
yes
Product
Development System
Tool Is For Evaluation Of
Atmega32
Core
AVR
Interface Type
Ethernet, RS-232, RS-485
Operating Supply Voltage
16 V to 30 V
Description/function
AVRPLC16 v6 board only, Telit GM862-GPS module with antennas and cables, UTP Cable, CAN-SPI board, MMC/SD card are sold separately
Dimensions
265 mm x 220 mm
AVRPLC16 v6
User manual
All MikroElektronika´s development systems represent irreplaceable
tools for programming and developing microcontroller-based devices.
Carefully chosen components and the use of machines of the last
generation for mounting and testing thereof are the best guarantee of
high reliability of our devices. Due to simple design, a large number of
add-on modules and ready to use examples, all our users, regardless
of their experience, have the possibility to develop their project in a fast

Related parts for MIKROE-551

MIKROE-551 Summary of contents

Page 1

... AVRPLC16 v6 All MikroElektronika´s development systems represent irreplaceable tools for programming and developing microcontroller-based devices. Carefully chosen components and the use of machines of the last generation for mounting and testing thereof are the best guarantee of high reliability of our devices. Due to simple design, a large number of ...

Page 2

... TO OUR VALUED CUSTOMERS Mikroelektronika. The primary aim of our company is to design and produce high quality electronic products and to constantly improve the performance thereof in order to better suit your needs. The Atmel name and logo, the Atmel logo, AVR, AVR (Logo), AVR Freaks, AVR Freaks (Logo), AVR Studio, IDIC, megaAVR, megaAVR (Logo), picoPower ® ...

Page 3

... AVRPLC16 v6 TABLE OF CONTENTS General information .......................................................................................................................... 4 Key features ..................................................................................................................................... 5 1.0. Connecting the development system to a power supply source ............................................... 6 2.0. ATMEGA32 microcontroller ....................................................................................................... 7 3.0. Programming microcontroller .................................................................................................... 8 4.0. MMC/SD connector ................................................................................................................... 11 5.0. RS-485 module ......................................................................................................................... 12 6.0. RS-232 module ......................................................................................................................... 13 7.0. ADC module .............................................................................................................................. 14 8.0. Ethernet module ........................................................................................................................ 15 9.0. GSM module ............................................................................................................................. 16 10.0. RTC module ............................................................................................................................ 19 11.0. A/D inputs ............................................................................................................................... 20 12.0. Relays and optocouplers ........................................................................................................ 21 13.0. I/O ports .................................................................................................................................. 22 3 MikroElektronika ...

Page 4

... ADC module, RTC module and MMC/SD connector. MikroElektronika The AVRFLASH ™ provides a complete list of all supported microcontrollers. The latest version of this program with updated list of supported microcontrollers can be downloaded from our website at www.mikroe.com Development system: AVRPLC16 v6 CD: product CD with relevant software Cables: ...

Page 5

... Microcontroller in DIP40 package 14. Real-time clock 15. Antenna holder 16. Screw terminals used to connect earphones and microphone 17. Serial Ethernet module 18. ADC module 19. RS-232 module 20. Connector for GSM/GPRS module 21. RS-485 module 22. Connector for MMC/SD memory card MikroElektronika 5 ...

Page 6

... When the development system is powered necessary to set switch marked POWER SUPPLY to the ON position, Figure 1-3. As soon as the development system is turned on, a green LED marked POWER will automatically illuminate. MMC/SD connector connection schematic MikroElektronika AVRPLC16 v6 Power supply voltage regulator Figure 1-4: POWER LED ...

Page 7

... The microcontroller provided on the development system can be easily replaced with another one in DIP40 package. When choosing another microcontroller very important to compare its and ATMEGA32’s pinouts to make sure that they are compatible. If you use a microcontroller with different pinout, some modules on the development system will probably not work. Microcontroller’s pinout MikroElektronika 7 ...

Page 8

... Figure 3-1: AVRprog programmer microcontroller. The on-board programmer is connected to the PC via a USB cable, Figure 3-2 (A and B). A Figure 3-2: Programmer and PC connection with the development system. To learn more about the AVRFLASH program, refer to the relevant manual that also comes along with the development system. MikroElektronika B AVRPLC16 v6 ...

Page 9

... Figure 3. Multiplexing In addition to the on-board programmer, the microcontroller can be programmed with the AVR ISP external programmer that is connected to the development system via the CN45 connector. The JTAG emulator, connected via a 2x5 connector CN46, can also be used for programming. External programmer 9 MikroElektronika ...

Page 10

... In this case they can be used as I/O pins J1-J5 in Enabled position, the microcontroller’s programming pins are connected to the programmer B J1-J5 in Disabled position, the microcontroller’s programming pins are not connected to the programmer MikroElektronika B The position of jumper J10 B The position of jumpers J1-J5 AVRPLC16 v6 ...

Page 11

... To connect a memory card to the microcontroller necessary to set switches 4, 5 and 6 on the DIP switch SW9, as well as switches 7 and 8 on the DIP switch SW10 to the ON position. Figure 4-3: The position of DIP switches SW9 and SW10 MMC/SD connector connection schematic A Figure 4-2: Inserting MMC/SD card 11 B MikroElektronika ...

Page 12

... RS-485 standard. The connection between this module and one of these devices is established via a screw connector CN10, Figure 5-2. In order to turn on this module necessary to set switches 1,2 and 3 on the DIP switch SW9 to the ON position, Figure 5-3. Figure 5-1: RS-485 module RS-485 module connection schematic MikroElektronika Figure 5-2: RS-485 connector AVRPLC16 v6 Figure 5-3: DIP switch SW9 ...

Page 13

... RS-232 standard. The connection between this module and one of these devices is established via screw terminals CN4 and CN5, Figure 6-2. In order to turn on this module necessary to set switches 1 and 2 on the DIP switch SW11 to the ON position, Figure 6-3. Figure 6-1: RS-232 module RS-232 module connection schematic Figure 6-2: RS-232 connector 13 Figure 6-3: DIP switch SW11 MikroElektronika ...

Page 14

... In order to enable the ADC module to be turned on, switches 4-7 on the DIP switch SW9 should be set to the ON position, Figure 7-3. Jumper 11 is used as a voltage reference source selector, Figure 7-4. Figure 7-3: DIP switch SW9 ADC module connection schematic MikroElektronika Figure 7-2: ADC module’s connector A B Figure 7-4: The position of jumper J11 ...

Page 15

... DIP switch SW9 as well as switches 1, 2 and 3 on the DIP switch SW10 should be set to the ON position, Figure 8-2. Figure 8-1: Ethernet module A Figure 8-3: Connecting ethernet cable Ethernet module connection schematic B Figure 8-2: DIP switches SW9 and SW10 MikroElektronika 15 ...

Page 16

... Screw the nut on the antenna terminal When the cable is properly placed into the holder on the development system necessary to screw antenna on the screw, Figure 9-5. A Figure 9-5: Connecting antenna MikroElektronika Figure 9-2: Connecting Telit’s GM862 module B B AVRPLC16 v6 Figure 9-3: Telit’s GM862 module ...

Page 17

... The GSM module gives a possibility of making phone calls. To enable this function necessary to connect a speaker to a screw terminal CN43 as well as a microphone to a screw terminal CN44. For more information refer to the Telit’s loaded into the microcontroller. Figure 9-8: Connectors used to connect microphone and speaker B Figure 9-9: DIP switch SW11 C MikroElektronika 17 ...

Page 18

... GSM module connection schematic Teltit’s modules GM862-QUAD and GM862-GPS may be used with this development system. MikroElektronika AVRPLC16 v6 ...

Page 19

... Pins on the DS1307 circuit that are used for connection with the microcontroller are marked as follows: OUT - Square wave/output driver SCL - Serial clock input SDA - Serial data input/output RTC module connection schematic 2 C serial interface. In order to establish connection between them Figure 10-2: DIP switch SW10 19 MikroElektronika ...

Page 20

... In addition to the ADC module, A/D conversion may also be performed by the A/D module built into the microcontroller. Tha A/D module converts analog voltage signal in a range between 0 and 5V. The conversion of an analog signal into set switches 1-8 on the DIP switch SW6 to the ON position. Figure 11-1: A/D inputs’ connectors A/D inputs connection schematic MikroElektronika Figure 11-2: DIP switch SW6 AVRPLC16 v6 ...

Page 21

... In order to enable optocouplers’ inputs necessary to set switches 1-8 on the DIP switch SW5 to the ON position. To enable relays necessary to se switches 1-8 on the DIP switches SW7 and SW8 to the ON position. Figure 12-3: Relays and optocouplers and microcontroller connection schematic Figure 12-2: Optocouplers with connectors MikroElektronika 21 ...

Page 22

... The microcontroller pins used for programming are not directly connected to the appropriate 10-pin connector, but via the multiplexer. DIP switches SW1-SW4 enable each connector pin to be connected to one pull-up/pull-down resistor. It depends on the position of jumpers J6-J9 whether the port pins are to be connected to pull-up or pull-down resistors. Figure 13-4: Port PORTA connection schematic MikroElektronika I/O ports AVRPLC16 pull-down ...

Page 23

... HIGH RISK ACTIVITIES The products of MikroElektronika are not fault – tolerant nor designed, manufactured or intended for use or resale as on – line control equipment in hazardous environments requiring fail – safe performance, such as life support machines or weapons systems in which the failure of Software could lead directly to death, personal injury or severe physical or environmental damage (‘ ...

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