mikromedia for PIC32 PIC32 Compact development system rich with on-board peripherals for all-round multimedia development on PIC32MX460F512L device.

Transcription

1 mikromedia for PIC Compact development system rich with on-board peripherals for all-round multimedia development on PICMX60F5L device. PIC

2 TO OUR VALUED CUSTOMERS I want to express my thanks to you for being interested in our products and for having confidence 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. Nebojsa Matic General Manager

3 Table of contents Introduction to mikromedia for PIC Package contains 5 Key features 6 System specification 7. Power supply 8 Battery power supply 8 USB power supply 8. PICMX60F5L microcontroller 0 Key microcontroller features 0. Programming the microcontroller Programming with mikrobootloader step Connecting mikromedia step Browsing for.hex file step Selecting.HEX file step Uploading.HEX file step 5 Finish upload 5 Programming with mikroprog programmer 6 mikroprog Suite for PIC software 7 Programming with ICD or ICD programmer 8. Reset button 0 5. Crystal oscillator 6. microsd card slot 7. Touch screen 6 8. Audio module 8 9. USB connection 0 0. Accelerometer. Flash memory. Pads 6. Pinout 7. Dimensions 8 5. mikromedia accessories 9 What s next? 0 Page

4 Introduction to mikromedia for PIC The mikromedia for PIC is a compact development system with lots of on-board peripherals which allow development of devices with multimedia contents. The central part of the system is a -bit PICMX60F5L microcontroller. The mikromedia for PIC features integrated modules such as stereo MP codec, TFT 0x0 touch screen display, accelerometer, USB connector, audio connector, MMC/SD card slot, 8 Mbit flash memory, x6 connection pads and other. It comes pre-programmed with USB HID bootloader, but can also be programmed with external programmers, such as mikroprog or ICD/. Mikromedia is compact and slim, and perfectly fits in the palm of the hand, which makes it convenient platform for mobile devices. Page

5 Package contains 0 Damage resistant protective box 0 mikromedia for dspic development system mikromedia for PIC - pinout 5V power supply VSYS RST Reset pin GND GND Reference Ground RB0 L left ch. RB R right ch. audio out RB RD0 Analog Lines RB RD RB PWM lines RD RB5 RD RB RA0 RE8 RA Interrupt Lines RE9 RA RA RA5 RA5 RA6 RA0 RA7 RC Digital I/O lines RD0 RB6 RD Digital I/O lines RB7 RD RF RD5 RG RF RG RF5 RG RF RX SCK RG6 RF8 TX UART SPI SDI RG7 RA SCL SDO SDA I C RG8 RA.V power supply.v.v.v power supply Reference Ground GND GND Reference Ground Pin functions Pin functions Digital lines Analog Lines Interrupt Lines SPI Lines IC Lines UART lines PWM lines 0 User s guide, schematic and pinout 0 USB cable, two x6, one x6 and one x5 male headers Page 5

6 Key features 09 0 Connection Pads 0 TFT 0x0 display 0 USB MINI-B connector 0 CHARGE indication LED 05 LI-Polymer battery connector mm headphone connector 07 Power supply regulator 08 Serial Flash memory 09 RESET button 0 VS05 Stereo mp coder/decoder PICMX60F5L microcontroller Accelerometer 0 Crystal oscillator Power indication LED 5 microsd Card Slot 6 ICD/ connector 7 mikroprog connector Page 6

7 System specification 06 power supply Via USB cable (5V DC) power consumption 58 ma with erased MCU (when on-board modules are inactive) 0 board dimensions 8. x 60.5 mm (.9 x.8 inch) weight ~50g (0.lbs) class B product Product complies with the Class B limit of EN 550 and can be used in the domestic, residential, commercial and industrial environments CAUTION: Electrostatic Sensitive Device Permanent damage may occur on devices subjected to high energy electrostatic discharges which readily accumulate on the human body or test equipment and can discharge without detection. Page 7

8 . Power supply USB power supply Figure -: Connecting USB power supply You can apply power supply to the board using MINI-B USB cable provided with the board. On-board voltage regulators provide the appropriate voltage levels to each component on the board. Power LED (GREEN) will indicate the presence of power supply. Battery power supply You can also power the board using Li-Polymer battery, via on-board battery connector. On-board battery charger circuit MCP78 enables you to charge the battery over USB connection. LED diode (RED) will indicate when battery is charging. Charging current is ~50mA and charging voltage is.v DC. Figure -: Connecting Li-Polymer battery Page 8

9 Page 9 5 VCC-BAT D PMEG00ER R K9 Charging Current approx. 50mA R9 K7 E7 C0.uF R K7 R6 K7 VCC-BAT VSENSE VCC-SYS VCC-SYS R 0K R7 0K R6 0K STAT R8 0K R5 K E5 R5 0K R9 K7 M DMP60UW STAT VBAT PROG U5 MCP78 Q BC86 Q5 BC86 FP FERRITE VCC-USB C9.uF R6 00K E0 R7 0K VCC-.8 VCC-.8 R50 0R 5 Vin GND EN ADJ Vout U MIC505-ADJ DATA BUS LD CHARGE VCC-BAT VCC-.8 VREF-.8 E FP FERRITE CN BATT CONN C8 0nF VBUS D- D+ ID GND 5 CN USB MINIB VCC-SYS E E R6 K Vout Vin GND REG LD9080DT LD POWER HDR MX HDR MX6 VCC-SYS Figure -: Power supply schematics

10 . PICMX60F5L microcontroller The mikromedia for PIC development system comes with the PICMX60F5L microcontroller. This high-performance -bit microcontroller with its integrated modules and in combination with other on-board modules is ideal for multimedia applications. Key microcontroller features -.56 DMIPS/MHz, -bit MIPS MK Core; - 5K Flash (plus K boot Flash); - K RAM (can execute from RAM); - 85 I/O pins; - SPI, I C, A/D; - 6-bit, -bit Digital Timers; - Internal Oscillator 8MHz, khz; - RTCC; etc. MIPS MK -bit core - 80MHz,.5 DMIPS/MHz - 5 Stage Pipeline, -bit ALU Trace -bit JTAG HW Mul/Div Instruction Data Prefetch Buffer Cache 6-bit Parallel Port RTCC 6 Ch 0-bit ADCs Core Registers Shadow Set Flash SRAM IC () Bus Matrix Peripherial Bus Input Capture (5) UARTs () PIC DMA Ch Interrupt Controller Output Compare PWM(5) SPI () -wire Debug GPIO (85) 6-bit Timers (5) VREG Analog Comparators () USB OTG Page 0

11 . Programming the microcontroller Figure -: PICMX60F5L microcontroller The microcontroller can be programmed in three ways: 0 Over USB HID mikrobootloader 0 Using mikroprog external programmer 0 Using ICD/ external programmer Page

12 Programming with mikrobootloader You can program the microcontroller with bootloader which is preprogrammed into the device by default. To transfer.hex file from a PC to MCU you need bootloader software (mikrobootloader USB HID) which can be downloaded from: step Connecting mikromedia mikrobootloader_usb_hid_stmf07vgt6.zip Upon download, unzip it to desired location and start the mikrobootloader application: 0 Figure -: USB HID mikrobootloader window 0 To start, connect the USB cable, or if already connected press the Reset button on your mikromedia board. Click the Connect button within 5s to enter the bootloader mode, otherwise existing microcontroller program will execute. Page

13 step Browsing for.hex file step Selecting.HEX file Figure -: Browse for HEX Figure -: Selecting HEX 0 Click the Browse for HEX button and from a 0 pop-up window (Figure.) choose the.hex file which will be uploaded to MCU memory. 0 Select.HEX file using open dialog window. Click the Open button. Page

14 step Uploading.HEX file 0 0 Figure -5: Begin uploading Figure -6: Progress bar 0 To start.hex file bootloading click the 0 Begin uploading button. Progress bar enables you to monitor.hex file uploading. Page

15 step 5 Finish upload 0 Figure -7: Restarting MCU Figure -8: mikrobootloader ready for next job 0 Click OK button after the uploading process is finished 0 Press Reset button on mikromedia board and wait for 5 seconds. Your program will run automatically Page 5

16 Programming with mikroprog programmer The microcontroller can be programmed with mikroprog programmer and mikroprog Suite for PIC software. The mikroprog programmer is connected to the development system via the CN6 connector, Figure -9. Figure -9: Connecting mikroprog to mikromedia mikroprog is a fast USB.0 programmer with mikroicd hardware In-Circuit Debugger. Smart engineering allows mikroprog to support PIC0, PIC, PIC6, PIC8, dspic0/, PIC and PIC devices in a single programmer. It supports over 570 microcontrollers from Microchip. Outstanding performance, easy operation and elegant design are it s key features. Page 6

17 mikroprog Suite for PIC software PIC mikroprog programmer requires special programming software called mikroprog Suite for PIC. This software is used for programming of ALL Microchip microcontroller families, including PIC0, PIC, PIC6, PIC8, dspic0/, PIC and PIC. Software has intuitive interface and SingleClick programming technology. Just by downloading the latest version of mikroprog Suite your programmer is ready to program new devices. mikroprog Suite is updated regularly, at least four times a year, so your programmer will be more and more powerful with each new release. Figure -0: Main window of mikroprog Suite for PIC programming software Page 7

18 Programming with ICD or ICD programmer The microcontroller can be also programmed with ICD or ICD programmer. These programmers connects with mikromedia board via ICD CONNECTOR BOARD. Figure -: Connecting ICD or ICD programmer In order to enable the ICD and ICD programmers to be connected to the mikromedia board, it is necessary to provide the appropriate connector such as the ICD CONNECTOR BOARD. This connector should be first soldered on the CN5 connector. Then you should plug the ICD or ICD programmer into it, Figure -. Page 8

19 Page 9 Figure -: mikroprog & ICD / ICD programmer connection schematic ICD/ MCLR# PGD PGC MCLR# PGD PGC R5 00 R 00 RB6 RB7 mikroprog 5 CN6 MX5 5 6 CN5 MX6 MCLR# PGD PGC Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L C5 C6 C7 C8 C5 E8

20 . Reset button Board is equipped with reset button, which is located at the top of the front side (Figure -). If you want to reset the circuit, press the reset button. It will generate low voltage level on microcontroller reset pin (input). In addition, a reset can be externally provided through pin 7 on side headers (Figure -). NOTE You can also solder additional reset button on the appropriate place at the back side of the board, Figure -. Figure -: Location of additional reset button Figure -: Frontal reset button Page 0

21 Page HDR MX6 RST R8 0K C T BUTTON R7 00 T BUTTON RST C5 C6 C7 C8 C5 X 8MHz C pf C pf X.768kHz C pf C0 pf CLKO CLKI SOSCO SOSCI E8 Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L RST Figure -: Reset circuit schematic

22 5. Crystal oscillator Figure 5-: External crystal oscillator (X) Board is equipped with 8MHz crystal oscillator (X) circuit that provides external clock waveform to the microcontroller CLKO and CLKI pins. This base frequency is suitable for further clock multipliers and ideal for generation of necessary USB clock, which ensures proper operation of bootloader and your custom USB-based applications. Board also contains.768khz Crystal oscillator (X) which provides external clock for internal RTCC module. NOTE The use of crystal in all other schematics is implied even if it is purposely left out because of the schematics clarity. Page

23 Page Figure 5-: Crystal oscillator schematic X 8MHz C pf C pf X.768kHz C pf C0 pf CLKO CLKI SOSCO SOSCI Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L C5 C6 C7 C8 C5 E8

24 6. microsd card slot Figure 6-: microsd card slot Board contains microsd card slot for using microsd cards in your projects. It enables you to store large amounts of data externally, thus saving microcontroller memory. microsd cards use Serial Peripheral Interface (SPI) for communication with the microcontroller. Page

25 Page 5 SD-CS# SD-CD# VCC-MMC R6 7 E6 C8 FP FERRITE CS Din +.V SCK 5 GND 6 Dout 7 CD G CN MMC CARD MICRO MOSI-RG8 SCK-RG6 MISO-RG7 R 0K R0 0K VCC-MMC R9 0K X 8MHz C pf C pf X.768kHz C pf C0 pf SD-CS# MOSI-RG8 SCK-RG6 SD-CD# CLKO CLKI SOSCO SOSCI MISO-RG7 R5 7 R 7 Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L C5 C6 C7 C8 C5 E8 Figure 6-: microsd Card Slot module connection schematic

26 7. Touch screen The development system features a TFT 0x0 display covered with a resistive touch panel. Together they form a functional unit called a touch screen. It enables data to be entered and displayed at the same time. The TFT display is capable of showing graphics in 6. diffe rent colors. Figure 7-: Touch Screen Page 6

27 Page 7 Figure 7-: Touch Screen connection schematic LCD-RST PMD5 PMD6 PMD7 LCD-RS LCD-CS# LCD-YU LCD-XL LCD-YD LCD-XR LCD-BLED PMRD PMWR PMD PMD PMD PMD PMD0 PMD8 PMD9 PMD0 PMD PMD PMD PMD5 PMD Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L R K VCC-SYS LCD-RST LCD-RS LCD-CS# LCD-YU LCD-XL LCD-YD LCD-XR E R5 0K R 0K LCD-RST LCD-CS# LCD-BLED R 00K R 00K LCD-YU LCD-XL Q BC86 R0 VCC-SYS Q BC86 Q BC86 PMRD PMWR C 8nF C 8nF D BAT PMD8 PMD9 PMD0 PMD PMD5 PMD PMD PMD PMD PMD PMD5 PMD6 PMD7 PMD PMD PMD0 C5 C6 C7 C8 C5 E8 TFT MI 08QT-9A L ED- A DB7 HSYNC RD VSYNC WR(D/C) L ED- A L ED- A L ED- A IM0 DE IM IM IM DOTCL K GND SDO RESET D/C(SCL) CS TE I X+(R) Y+(D) X- (L ) SDI L ED- K Y- (U) DB6 DB5 DB DB DB DB DB0 DB9 DB8 DB7 DB6 DB5 DB DB DB DB DB0 VCI VCI

28 8. Audio module Figure 8-: On-board VS05 MP codec The mikromedia for PIC features stereo audio codec VS05. This module enables audio reproduction by using stereo headphones connected to the system via a.5mm connector CN. All functions of this module are controlled by the microcontroller over Serial Peripheral Interface (SPI). Page 8

29 Page 9 Figure 8-: Audio module connection schematic MP-BSYNC MP-CS# C0 pf C9 pf R M R0 0K R 0K MP-DREQ MP-RST# R 0K R9 0K X.88MHz C uf GPIO LEFT RIGHT GBUF E E CN PHONEJACK LEFT RIGHT C6 0nF C 7nF C5 0nF R7 0 R0 0 R 0 R8 0 R9 0 R 70 C7.nF R7 00K R 70 C8.nF R8 00K L R R 7 MCN XRESET DGND0 C0 5 IO0 6 C 7 GPIO6 GPIO7 XDCS/BSYNC IO GPIO5 5 C XCS DGND DGND XTALI 8 XTALO 7 DGND 6 VCO 5 DREQ 8 MCP/LN IO 9 GPIO 9 GPIO 0 TX 7 RX 6 DGND 0 SCLK 8 SI 9 SO 0 C XTEST GPIO0 GPIO GND 5 GPIO 6 AGND0 7 A0 8 RIGHT 9 AGND 0 AGND GBUF A RCAP A 5 LEFT 6 AGND 7 LN 8 U VS05 VCC-.8 MP-CS# MP-RST# SCK-RG6 MOSI-RG8 MISO-RG7 MOSI-RG8 SCK-RG6 MP-CS# MP-BSYNC MP-DREQ MP-RST# MISO-RG7 R5 7 R 7 Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L C C0 C C9 VCC-.8 VCC-.8 VCC-.8 VCC-.8 C C C C6 C7 C5 C6 C7 C8 C5 E8

30 9. USB connection Figure 9-: Connecting USB cable to MINI-B USB connector PICMX60F5L microcontroller has integrated USB module, which enables you to implement USB communication functionality to your mikromedia board. Connection with target USB host is done over MINI-B USB connector which is positioned next to the battery connector. Page 0

31 Page Figure 9-: USB module connection schematic X 8MHz C pf C pf X.768kHz C pf C0 pf CLKO CLKI USB-DET USBDP USBDM SOSCO SOSCI USB-ID-RF Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L USBDP USBDM VCC-USB C8 0nF FP FERRITE VBUS D- D+ ID GND 5 CN USB MINIB USB-ID USB-DET R 00 USB-ID-RF USB-ID RF J SMD JUMPER C5 C6 C7 C8 C5 E8

32 0. Accelerometer Figure 0-: Accelerometer module On board ADXL5 accelerometer is used to measure acceleration in three axis: x, y and z. The accelerometer function is defined by the user in the program loaded into the microcontroller. Communication between the accelerometer and the microcontroller is performed via the I C interface. You can set the accelerometer address to 0 or by re-soldering the SMD jumper (zero-ohm resistor) to the appropriate position. Jumper is placed in address position by default. Page

33 Page Figure 0-: Accelerometer connection schematic C C R 0K R 0K J SMD JUMPER ACC ADDRESS VCC GND Res GND 5 GND 6 VCC 7 CS 8 INT 9 INT 0 NC Res ADD SDA SCL U9 ADXL5 SDA-RA SCL-RA SDA-RA SCL-RA Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L C5 C6 C7 C8 C5 E8

34 . Flash memory Figure -: Flash memory module Since multimedia applications are getting increasingly demanding, it is necessary to provide additional memory space to be used for storing more data. The flash memory module enables the microcontroller to use additional 8Mbit flash memory. It is connected to the microcontroller via the Serial Peripheral Interface (SPI). Page

35 Page 5 MOSI-RG8 SCK-RG6 FLASH-CS# MISO-RG7 R5 7 R 7 Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L FLASH-CS# C7 R8 0K CS SDO WP SDI 5 GND SCK 6 HOLD 7 VCC 8 U0 M5P80 MISO-RG7 SCK-RG6 MOSI-RG8 C5 C6 C7 C8 C5 E8 Figure -: Flash memory module connection schematic

36 . Pads Most microcontroller pins are available for further connectivity via two x6 rows of connection pads on both sides of the mikromedia board. They are designed to match additional shields, such as Battery Boost shield, Gaming, PROTO shield and others. Note: pin RA0 can be used either as an I/O or as VREF.8. (to switch between those, solder jumper J in appropriate position). Pads HDR Pads HDR Page 6

37 Page 7 RX TX SDA SCL RST R L HDR MX6 RD RD RD5 RD RD RX-RF TX-RF8 RA RA6 RF RF5 RA7 RA5 RA RA0 RD0 RD SDA-RA SCL-RA RD0 SCK SDI SDO HDR MX6 VCC-SYS RA0 RE9 RE8 RB0 MOSI-RG8 SCK-RG6 MISO-RG7 RB RB RB RB RB5 RB RA RA5 RG RG RG RC RB6 RB7 RF MOSI-RG8 SCK-RG6 RB0 RE9 RE8 RB RB RB RB RB5 RA0 RC RD RD5 RB RA RF RF5 RF RD SDA-RA SCL-RA RX-RF TX-RF8 RA RA5 RA5 RA RD0 RD0 RD RD RA6 RG RG RG RA7 RD RA0 RB7 RB6 MISO-RG7 R5 7 R 7 Vcap E9 6 RE6 RE5 RB0 5 RB RB RB RB RB5 0 RE7 5 RG6/SCK 0 RG7/SDI 5 RG9 RG8/SDO MCLR RG5 RC 6 RC 7 RC 8 RC 9 RA0/TMS 7 RE8/INT 8 RE9/INT 9 RB 5 A 0 RB9 RB8 RB RB RB5 RB RF 9 RF RB6 6 A RB0 RB7 7 7 RA9 8 RA0/VREF+ 9 RA 8 RF 9 RF 0 RD 7 RD RC 7 RC 7 RD0 7 RD 7 RD D+/RG 57 RF 5 URX/RF 5 VUSB 55 D-/RG 56 OSC 6 RD8 68 OSC 6 RD RA 66 RA5 67 RA 60 RA5 6 SCL/RA 58 SDA/RA 59 UTX/RF8 5 VBUS 5 RD 77 RF0 87 RD7 8 RD6 8 RD5 8 RD 8 RE 00 ENVREG 86 Vcap/core 85 RD 76 RE0 9 RD 78 RF 88 RE 9 RE 98 RE 99 RG 97 RG 96 RG 95 RA7 9 RA6 9 RG0 90 RG 89 RD 80 RD 79 U PICMX60F5L R7 00 RST Figure -: Connection pads schematic

38 . Pinout 5V power supply SCK SPI SDI SDO.V power supply Reference Ground Pin functions Analog Lines Interrupt Lines Digital I/O lines VSYS RST GND GND RB0 L RB R RB RD0 RB RD RB RD RB5 RD RB RA0 RE8 RA RE9 RA RA RA5 RA5 RA6 RA0 RA7 RC RD0 RB6 RD RB7 RD RF RD5 RG RF RG RF5 RG RF RG6 RF8 RG7 RA RG8 RA.V.V GND GND Reset pin Reference Ground left ch. right ch. audio out PWM lines Digital I/O lines RX TX UART SCL SDA I C.V power supply Reference Ground Pin functions Digital lines Analog Lines Interrupt Lines SPI Lines IC Lines UART lines PWM lines Page 8

39 . Dimensions Legend Page 9

40 5. mikromedia accessories We have prepared a set of extension boards pin-compatible with your mikromedia, which enable you to easily expand your board s basic functionality. We call them mikromedia shields. But we also offer other accessories, such as Li-polymer battery, stacking headers, wire jumpers and more. 0 Connect shield 0 BatteryBoost shield 0 PROTO shield 0 Gaming shield 05 mikrobus shield 06 Li-Polimer battery 07 Wire jumpers Page 0

41 What s next? You have now completed the journey through each and every feature of mikromedia for PIC board. You got to know its modules and organization. Now you are ready to start using your new board. We are suggesting several steps which are probably the best way to begin. Find useful projects and tutorials on the Libstock website ( Join our Forum ( and get help from a large ecosystem of users. Compiler You still don t have an appropriate compiler? Locate PIC compiler that suits you best on our site: Choose between mikroc, mikrobasic and mikropascal and download a fully functional demo version, so you can begin building your first applications. Visual TFT Once you have chosen your compiler, and since you already got the board, you are ready to start writing your first projects. Visual TFT software enables you to quickly create your GUI. It will automatically generate code compatible with МikroElektronika compilers. Visual TFT is rich with examples, which are an excellent starting point for your future projects. Download it from the link bellow: Page

42 Notes: Page

43 DISCLAIMER All the products owned by MikroElektronika are protected by copyright law and international copyright treaty. Therefore, this manual is to be treated as any other copyright material. No part of this manual, including product and software described herein, may be reproduced, stored in a retrieval system, translated or transmitted in any form or by any means, without the prior written permission of MikroElektronika. The manual PDF edition can be printed for private or local use, but not for distribution. Any modification of this manual is prohibited. MikroElektronika provides this manual as is without warranty of any kind, either expressed or implied, including, but not limited to, the implied warranties or conditions of merchantability or fitness for a particular purpose. MikroElektronika shall assume no responsibility or liability for any errors, omissions and inaccuracies that may appear in this manual. In no event shall MikroElektronika, its directors, officers, employees or distributors be liable for any indirect, specific, incidental or consequential damages (including damages for loss of business profits and business information, business interruption or any other pecuniary loss) arising out of the use of this manual or product, even if MikroElektronika has been advised of the possibility of such damages. MikroElektronika reserves the right to change information contained in this manual at any time without prior notice, if necessary. 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 traffic 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 ( High Risk Activities ). MikroElektronika and its suppliers specifically disclaim any expressed or implied warranty of fitness for High Risk Activities. TRADEMARKS The MikroElektronika name and logo, mikroc, mikrobasic, mikropascal, Visual TFT, Visual GLCD, mikroprog, Ready, MINI, mikrobus, EasyPIC, EasyAVR, Easy805, click boards and mikromedia are trademarks of MikroElektronika. All other trademarks mentioned herein are property of their respective companies. All other product and corporate names appearing in this manual may or may not be registered trademarks or copyrights of their respective companies, and are only used for identification or explanation and to the owners benefit, with no intent to infringe. The PIC and Windows logos and product names are trademarks of Microchip Technology and Microsoft in the U.S.A. and other countries. Copyright 0 MikroElektronika. All Rights Reserved. Page

44 PIC If you want to learn more about our products, please visit our web site at If you are experiencing some problems with any of our products or just need additional information, please place your ticket at If you have any questions, comments or business proposals, do not hesitate to contact us at mikromedia for PIC Manual ver..0f