MIKROE-510 mikroElektronika, MIKROE-510 Datasheet

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... Easy24-33 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 ™ ...

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... TO OUR VALUED CUSTOMERS I want to express my thanks to you for being interested in our products and for having confi dence in 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. ...

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... Power Supply ............................................................................................................................ 11 7.0. A/D Converter Test Inputs .......................................................................................................... 12 8.0. Serial EEPROM Module ............................................................................................................ 13 9.0. USB Communication Module .................................................................................................... 13 10.0. Serial RAM Module ................................................................................................................. 14 11.0. RS-232 Communication Module ............................................................................................. 15 12.0. CAN Communication Module ................................................................................................. 16 13.0. ZigBee Communication Module ............................................................................................. 17 14.0. USB UART Module ................................................................................................................. 18 15.0. Piezo Buzzer ........................................................................................................................... 19 16.0. DS1820 Temperature Sensor .................................................................................................. 20 17.0. LEDs ........................................................................................................................................ 21 18.0. Push Buttons ........................................................................................................................... 22 19.0. Touch Sense Keypad .............................................................................................................. 23 20.0. 2x16 LCD ................................................................................................................................ 24 21.0. I/O Ports ................................................................................................................................. 25 3 MikroElektronika ...

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... Numerous modules, such as ZigBee The mikroProg Suite for PIC program 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: Easy24-33 v6 CD: product CD with relevant software ...

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... Push buttons for exciting microcontroller digital inputs 22. Jumper for protective resistor shortening 23. Jumper for selecting push buttons’ logic state 24. Reset button 25. CAN communication module 26. ZigBee communication module 27. Alphanumeric LCD connector 28. Connector for RS-232 communication 29. Connector for DS1820 temperature sensor MikroElektronika ...

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... Follow the instructions provided in the relevant manuals and install the mikroProg Suite for PIC program and USB driver from the product CD. USB drivers are essential for the proper operation of the on-board programmer. In case you already have one of the Mikroelektronika’s dsPIC compilers installed on your PC, there is no need to reinstall USB drivers as they are already installed along with the compiler. ...

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... Pin RA3 is fed with a clock signal from external oscillator X1 (OSC1) I/O J12 OSC Pin RA2 is fed with a clock signal from external oscillator X1 (OSC1) I/O J4 OSC Pin RB2 is fed with a clock signal from external oscillator X2 (OSC2) I/O J3 OSC Pin RB1 is fed with a clock signal from external oscillator X2 (OSC2 Function MikroElektronika ...

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... Use the mikroProg Suite for PIC program to select the microcontroller you 3 Click the Write button to dump the code into the microcontroller. Programming process MikroElektronika mikroProg Suite for PIC program. Figure 3-3 shows connection Programmer’s USB connector 2 The mikroProg Suite for PIC program’s main window includes options microcontroller memory ...

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... The process of testing and debugging is performed by monitoring the state of all registers within the microcontroller while operating in real environment. The mikroICD software is integrated in all PIC compilers designed by Mikroelektronika (mikroBASIC PRO, mikroC PRO, mikroPASCAL PRO, etc.). As soon as the mikroICD debugger starts up, a window called Watch Values, appears on the screen, Figure 4-1. The mikroICD debugger communicates to the microcontroller through the microcontroller’ ...

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... Figure 5-2: Pins RB0 and RB1 are (default position) used for programming External ICD programmer is connected to RB0 and RB1 pins ICD connector and microcontroller connection schematic MikroElektronika Easy24-33 v6 Development System Figure 5-3: Pins RA0 and RA1 are Figure 5-4: Pins RB7 and RB6 are used for programming ...

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... EXT position. The development system is turned on/off by switching the position of the POWER SUPPLY switch. Power supply voltage regulator POWER SUPPLY switch Jumper J17 as a power supply source selector Figure 6-1: Power supply Powering over an AC/DC connector Figure 6-2: Power supply source connection schematic AC/DC connector USB connector Powering over a USB connector 11 MikroElektronika ...

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... Figure 7-3: A/D converter test inputs and microcontroller connection schematic In order to enable the microcontroller to accurately perform A/D conversion necessary to turn off LEDs and pull-up/ pull-down resistors on the port pins used by the A/D converter. MikroElektronika Easy24-33 v6 Development System Figure 7-2: Pins RA0 and RB0 used as input pins for A/D conversion ...

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... RB6, RB10, RB11 and RB12. When these jumpers are in the USB position (Figure 9-1), the microcontroller pins are used for USB communication. When they are in the I/O position, the microcontroller pins are used as I/O pins. Jumpers J8, J9, J10 and J11 are in USB position Figure 9-1: USB connector CN9 and microcontroller connection schematic 13 MikroElektronika ...

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... DIP switch SW1 is used to control the access to RAM. Figure 10-1: Serial RAM module Serial RAM is connected to the microcontroller via RB15, RB7, RB8, RB14 and RB9 pins Figure 10-2: Serial RAM module and microcontroller connection schematic MikroElektronika Easy24-33 v6 Development System 64Kbit RAM module can be added to the RAM module built ...

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... The function of switches 1-6 on the DIP switch SW1 is to determine which microcontroller pins are to be used as RX and TX lines. Port RS-232 is connected to the microcontroller Figure 11-2: RS-232 module and microcontroller connection schematic Make sure that your microcontroller is provided with the USART module not necessarily integrated in all PIC24 microcontrollers. RS-232 connector Figure 11-1: RS-232 module 15 MikroElektronika ...

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... DIP switch SW4 to the ON position. The RX line is connected to the microcontroller via the RB15 pin, whereas the TX line is connected to the microcontroller via the RB14 pin. Figure 12-1: CAN module CAN communication is enabled via DIP switch SW4 Figure 12-3: Microcontroller and CAN module connection schematic MikroElektronika Easy24-33 v6 Development System Figure 12-2: CAN module connector ...

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... ZigBee module is connected to the microcontroller through the DIP switches SW3 and SW4 Figure 13-3: ZigBee module and microcontroller connection schematic ZigBee module and microcontroller are connected through the DIP switch SW4 Serial SPI communication between ZigBee module and microcontroller is enabled through the DIP switch SW3 17 Figure 13-2: DIP switch SW3 MikroElektronika ...

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... RX pin not possible to directly connect UART’s and microcontroller’s TX lines since the microcontroller wouldn’t be able to receive nor send data. Figure 14-1: USB UART module USB connector of B type is connected to the microcontroller via the FT232RL circuit Figure 14-2: USB UART module and microcontroller connection schematic MikroElektronika Easy24-33 v6 Development System USB connector of B type ...

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... Figure 15-2, the voltage signal is generated through the RB8 pin. Piezo buzzer’s resonant frequency 3.8kHz Piezo buzzer is connected to the microcontroller via the RB8 pin Figure 15-2: Piezo buzzer and microcontroller connection schematic Figure 15-1: Piezo buzzer Transistor Q12 is used to amplify voltage signal generated by the microcontroller MikroElektronika 19 ...

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... Figure 16- RB9 Figure 16-1: DS1820 position connector (DS1820 is connected to the RB9 not placed) pin) Jumper J7 is placed in the RB9 position Figure 16-4: DS1820 temperature sensor and microcontroller connection schematic MikroElektronika Figure 16- RB8 (DS1820 is position (DS1820 is connected to the RB8 pin) Easy24-33 v6 Development System ...

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... LED indicates that a logic one (1) is present on the pin. In order to enable the pin state to be shown necessary to select appropriate port (PORTA or PORTB) using the DIP switch SW4. Figure 17-1: LEDs PORTB LEDs are turned on Figure 17-2: Microcontroller’s PORTB and LEDs connection schematic Notch indicating the SMD LED cathode Microcontroller SMD resistor limiting current MikroElektronika 21 ...

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... By pressing any push button when jumper the VCC-3.3, a logic one (3.3V) will be applied to the appropriate microcontroller pin, as shown in Figure 18-2. By pressing a push button, the appropriate pin will be driven high (1) Figure 18-2: Microcontroller’s PORTB and push buttons connection schematic MikroElektronika Easy24-33 v6 Development System Figure 18-1: Push buttons ...

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... Make sure that pull-up/pull-down resistors on pins RB0, RB1, RB2, RB3, RB12 and RB14 are disabled prior to using the touch sense keypad. Have in mind when writing program for the microcontroller that touch sense keypad is connected to port PORTB Copper surface is connected to the RB12 microcontroller pin It is surrounded by another copper surface connected to the ground MikroElektronika 23 ...

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... Communication between the LCD and the microcontroller is performed in a 4-bit mode. Alphanumeric digits are displayed in two lines each containing characters of 7x5 pixels. Figure 20-1. Connector for alphanumeric LCD LCD display backlight is on Alphanumeric 2x16 LCD and microcontroller connection schematic MikroElektronika Easy24-33 v6 Development System Contrast adjustment potentiometer Figure 20-2: Alphanumeric 2x16 LCD ...

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... Figure 21-1: I/O ports Port PORTB pins are connected to pull-down resistors Figure 21-3: Port PORTB connection schematic Additional board connected to pads On-board pads for placing additional components (proto board) Figure 21-2: Screw connectors are connected to I/O pins Additional board connected to port PORTB 25 MikroElektronika ...

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... Figure 20-4: Jumpers CN110 in pull-down position and jumper J6 in VCC-3.3 position Jumpers CN110 in pull-up and jumper J6 in GND position Jumpers CN10 and J6 in the same positions MikroElektronika Easy24-33 v6 Development System In order to enable the PORTB port pins to be connected to pull-down resistors necessary ...

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... 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 in the operation of nuclear facilities, aircraft navigation or communication systems, air traffi c control, direct 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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