user's guide to
mikrome iaboard for ARMCompact development system rich with on-board peripherals for
all-round multimedia development on LPC2148 ARM7 device
Page 3
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.
The Microchip, Atmel, NXP and CYPRESS name, logo and products names are trademarks of Microchip, Atmel, NXP and CYPRESS Inc. in the U.S.A and other countries.
TO OUR VALUED CUSTOMERS
Nebojsa Matic
General Manager
Page 3
Introduction to mikromedia for ARM 4
Related material 5
Key Features 6
System Specification 7
1. USB power supply 8
2. Battery power supply 9
3. Programing with In-System Programer 10
Settings 12
Flash magic software
step 1 – Choose Device 14
step 2 – Choose COM port 15
step 3 – Select baud rate 15
step 4 – Specify oscillator freq. 16
step 5 – Browse for .hex file 16
step 6 – Erase Flash 17
step 7 – Start Programming 18
step 8 – Finished! 18
4. LPC2148 Microcontroller 19
Key microcontroller features 19
5. Programing with JTAG programmer/debugger 20
6. microSD Card Slot 22
7. Accelerometer 23
8. Touch Screen 24
9. Audio Module 26
10. USB connection 28
11. Pads 30
12. Pinout 31
13. Dimensions 32
Table of Contents
Page 4 Page 5
Introduction to mikromedia for ARM
The mikromedia for ARM 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 32-bit ARM7
microcontroller LPC2148. The mikromedia
for ARM features integrated modules such
as stereo MP3 codec, TFT 320x240 touch screen display, accelerometer, two USB
connectors: one for communication with the
microcontroller one and for ISP programming,
MMC/SD card slot and other. Mikromedia is
compact and slim, and perfectly fits in the
palm of the hand, which makes it convenient
platform for mobile devices.
Page 4 Page 5
Related material
01 02
04 05
03
06
Damage resistant
protective box
mikromedia for ARM
development system
mikromedia for ARM
user’s guide
mikromedia for ARM
schematic
DVD with documentation
and examples
USB cable
schematic
Compact development system rich with on-board peripherals for all-round multimedia development on LPC2148 microcontroller
mikrome iaboard for ARM
Page 6 Page 7
Key Features
01
02
01
02
03
04
05
06
07
08
09
10
11
12
13
14
15
Connection Pads
TFT 320x240 display
USB MINI-B programmer connector
LI-Polymer battery connector
USB MINI-B device connector
3.5mm headphone connector
Power supply regulator
FTDI USB Uart controller
VS1053 Stereo mp3 coder/decoder
Power indicator LEDs
Accelerometer
LPC2148 microcontroller
RESET button
MicroSD Card Slot
JTAG connector
Page 6 Page 7
System Specification
power supply
Over a USB cable (5V DC)
board dimensions
8 x 6cm (3.14 x 2.36 inch)
weight
~50g (0.11 lbs)
power consumption
50mA in idle state
(when on-board modules are off)
03
06
07
08
09
1110
12
13
14
15
0405
Page 8 Page 9
1. USB power supply
You can provide power supply to the
board using either of the two miniUSB
connectors. On board voltage regulator
will make sure to generate the
appropriate voltage levels to each part
of the board. Power LED will indicate the
presence of power supply.
Figure 1-1: Powering your
mikromedia board with USB cables
Page 8 Page 9
Development system can be provided with power supply
using Li-Polymer battery, via on-board battery connector.
On-board battery charger circuit MCP73832 enables you
to charge the battery over USB power supply. Charging
current value is ~250mA and charging voltage is 4.2V DC.
VCC-5V
VCC-5V
VCC-BAT
R52
4K7R533K9
LD3
VSS
PROGSTAT
VDDVBAT
U6
STAT
MCP73832
D3
MBRS140T3
C35
2.2uF
VCC-5V VCC-BAT
E3
10uF
VCC-BAT
HDR3
M1X2
for Charging Current approx. 250mA
Figure 2-2: Li-polymer battery
connected to mikromedia
2. Battery power supply
Figure 2-1: Battery charger connecting schematic
Page 10 Page 11
The microcontroller can be programmed with In-System Programmer supported in the hardware itself. Programmer USB connector is connected
to the microcontroller through USB-UART connection.
3. Programming with
In-System Programmer
Figure 3-1: Connecting USB
cable to programming connector
note You have to download and install drivers for your USB-UART
connection before programming. Drivers can be found on
FTDI website: http://www.ftdichip.com/FTDrivers.htm
Page 10 Page 11
FP1FERRITE
VCC-3.3
OSCI
DTR#
OSCOTXD
TEST
VCC
RTS#
DSR#
AGND
RESET#
VCCIO
DCD#
NC
GND
RXD
CTS#
CBUS1
USBDM
GND
CBUS2
GND
USBDP
NC
CBUS3
CBUS0
3V3OUT
RI#
CBUS4
FT232RL
U2
VCC-FTDI
C19
100nF
VCC-3.3
C21
100nF
C20
C18
100nF
100nF
VCC-FTDI
E2
10uF
LPC2148
P1.
27P
0.31
GN
DP
0.0
P1.
31P
0.1
P0.
2V
CC
3P
1.26
GN
DP
0.3
P0.
4P
1.25
P0.
5P
0.6
P0.
7P
1.24
VR
EF
XTA
L1X
TAL2
P1.
28G
ND
AP
0.23
RE
SE
TP
1.29
P0.
20P
0.19
P0.
18P
1.30
VC
C3
GN
DV
BAT
P0.21 P1.20P0.17P0.16P0.15P1.21VCC3GND
P0.14P1.22P0.13P0.12P0.11P1.23P0.10
P0.9P0.8
P0.22RTXC1P1.19RTXC2GNDVCCAP1.18P0.25D+D-P1.17P0.28P0.29P0.30P1.16
VCC3
D2
P0.1
MCU-RST#
P0.14
P0.0R23
100
100
100
100
R24
R25
R26 MBRS340T3
CN3USB-ID ID 4
GND 5
USBDP D+ 3USBDM D- 2
VCC-USB VBUS 1
USB MINI-B
VCC-5V
VCC-FTDI
LD1
RED
R11
100VCC-3.3
Figure 3-1: ISP programming lines are connected with USB-UART
Page 12 Page 13
Device Manager on your PC contains informations on which COM
port is used for USB communication with the mikromedia board for
ARM. In this case the COM4 port is used.
01
Settings
01
02
03
03
From the drop menu select COM port on your PC.
02 Set Baud Rate to 19200.
Enter 12 in the Oscillator field (if you use different oscillator
enter its value in MHz instead).
04
04 Right click on USB port, then on properties in the
drop-down list.
06
05 Select the Port Settings tab from pop-up window.
06 Click on the Advanced... button.
05
Page 12 Page 13
07 In pop-up window uncheck the Serial Enumerator option and click OK.
07
note Steps 4 – 7 should be adjusted only once.
Page 14 Page 15
Figure 3-2: Flash Magic window after installation
step 1 – Choose Device
Figure 3-3: Selecting target device
01 Click on Select device button and browse for LPC2148
microcontroller from ARM7 family of microcontrollers.
01
Programming is done using specialized programming
software called Flash Magic, which is available for download
from the mikromedia for ARM webpage.
Flash Magic software
Page 14 Page 15
01 From the dropdown list select 19200 bps baudrate which
is the correct UART communication speed for mikromedia.
step 2 – Choose COM port step 3 – Select baud rate
Figure 3-4: Selecting COM Port
01 From the dropdown list choose the COM Port assigned
to your mikromedia board after connecting it to your PC
over USB cable.
01
Figure 3-5: Selecting baudrate
Page 16 Page 17
Figure 3-6: Specifying oscillator frequency Figure 3-7: Browsing for HEX file
step 4 – Specify oscillator freq. step 5 – Browse for .hex file
01 01Specify the value of on-board crystal oscillator 12.000 MHz Click on Browse and find the HEX file you want to program
your mikromedia with. The path to the target file will be
shown in the edit field.
01
01
01
Page 16 Page 17
Figure 3-8: Write programFigure 3-8: Erasing Flash memory before programming
step 6 – Erase Flash
01
01
Click on the Erase Flash icon in the main toolbar.
Tick the first checkbox to specify erasing the entire flash.
Click on Erase button to start erasing flash.
Click OK when Erasing is completed.02
03
01
01
02 03
Page 18 Page 19
Figure 3-10: Uploading is finishedFigure 3-9: Program uploading
step 7 – Start Programming step 8 – Finished!
01 01We are now ready to program the microcontroller.
Click on Start button to start uploading your program.
When everything is completed, you will receive a message
in the status bar.
01
01
Page 18 Page 19
The mikromedia for ARM development system comes with
the LPC2148 microcontroller. This high-performance 32-bit
microcontroller with its integrated modules and in combination
with other on-board modules is ideal for multimedia applications.
4. LPC2148 Microcontroller
Key microcontroller features - 32-bit architecture;
- 512KB of program memory;
- 32KB of RAM memory;
- 64 pins;
- 128 bit wide interface enables
high speed 60 MHz operation
- USB 2.0 Full Speed compliant Device
- 2-UART, 2-SPI, 2-I2C; etc.
- 16-bit/32-bit ARM7TDMI-S microcontroller in a tiny LQFP64 package.- 8 kB to 40 kB of on-chip static RAM and 32 kB to 512 kB of on-chip flash memory.
- 128-bit wide interface/accelerator enables high-speed 60 MHz operation.
- In-System Programming/In-Application Programming (ISP/IAP) via on-chip boot loader software.
Single flash sector or full chip erase in 400 ms and programming of 256 bytes in 1 ms.
- EmbeddedICE RT and Embedded Trace interfaces offer real-time debugging with theon-chip
RealMonitor software and high-speed tracing of instruction execution.- USB 2.0 Full-speed compliant device controller with 2 kB of endpoint RAM.
(In addition, the LPC2146/48 provides 8 kB of on-chip RAM accessible to USB by DMA).
- One or two (LPC2141/42 vs. LPC2144/46/48) 10-bit ADCs provide a total of 6/14 analog inputs,
with conversion times as low as 2.44 μs per channel.- Single 10-bit DAC provides variable analog output (LPC2142/44/46/48 only).
- Two 32-bit timers/external event counters (with four capture and four compare channels each),
PWM unit (six outputs) andwatchdog.- Low power Real-Time Clock (RTC) with independent power and 32 kHz clock input.
Key features
ARM7 Local Bus
LPC2148FAST GENERALPURPOSE I/O
TEST DEBUGINTERFACE PLL0
SYSTEMFUNCTIONSPLL1
ARM7TDMI-SAHB BRIDGE
systemclock
USBclock
AMBA AHB(Advanced High-performance BUS)
VECTORED INTERRUPT CONTROLLER
Internal SRAMcontroller
8 kB/16 kB/32 kB SRAM
32 kB/64 kB/128 kB/256 kB/512 kB
FLASH
Internal FLASHcontroller
AHB TO VPBBRIDGE
VPBDIVIDER
8 kB RAMSHARED WITHUSB DMA(3)
AHB DECODER
DATA BUS VPB (VLSI peripheral bus)EXTERNALINTERRUPT
CAPTURE/COMPARE
(W/EXTERNAL CLOCK)
TIMER 0/TIMER 1
D/A CONVERTER
PWM0
USB 2.0 FULL-SPEEDDEVICE CONTROLLERWITH DMA(3)
I2C-BUS SERIALINTERFACES 0 AND 1SYSTEMCONTROL
WATCHDOGTIMER
UART0/UART1
SPI AND SSPSERIAL
INTERFACES
A/D CONVERTERS0 AND 1(2)
GENERAL PURPOSE I/O
REAL-TIME CLOCK
Page 20 Page 21
Besides In-System programming mikromedia for ARM supports JTAG programming and
debugging interface. In order to use it, you have to solder 2x10 header to the JTAG connection
pads on the back side of your mikromedia board. It is also necessary to solder and set the JTAG jumper, located right next
to the JTAG connector (Figure 5-1), in order to enable this type of programming.
5. Programing with JTAG
programmer/debugger
Figure 5-1: Enabling JTAG using jumper
Page 20 Page 21
M2X10
P1.27 R6
P1.31 R1
P1.28R2
P1.29
P1.26
R4
P1.30
CN4
P1.31P1.28P1.30P1.29P1.26P1.27MCU-RST#
R3
Figure 5-2: JTAG interface schematics
Page 22 Page 23
6. microSD Card Slot
P1.24
P0.6
P0.4
P0.5
FP2
FERRITE
CN5MICROSD CARD
G CD
R34 27
R32 27
R33 27
Board contains microSD card slot for using microSD cards
in your projects. It enables you to store large ammounts of
data externally, thus saving microcontroller memory. microSD
cards use Serial Peripheral Interface (SPI) for communication
with the microcontroller.
Figure 6-1: Inserting microSD card
Figure 6-2: microSD card
Page 22 Page 23
VCC-3.3
ADXL345
R1610K
R1510K
U3
VCC
GND
NC
GND
GND
VCCC
SSC
LK SDI
SDO
NC
NC
INT2
INT1AD
XL34
5
C11
100nF
VCC-3.3
C12
100nF
VCC-3.3
P0.2
P0.3
VCC-3.3 VCC-3.3
7. Accelerometer
The accelerometer is used to measure acceleration
in three axis: x- y- and z-. The acceleromer’s function
is defined by the user in the program loaded into
the microcontroller. Communication between the
accelerometer and the microcontroller is performed
over the I2C interface.
Figure 7-2: Accelerometer connecting schematic
Figure 7-1: Accelerometer
module
Page 24 Page 25
The development system features a TFT 320x240 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 data in 262.000 diffe rent colors.
8. Touch Screen
Figure 8-1: Touch Screen
There are two SMD jumpers, or zero-
ohm resistors on board for selection
of TFT communication mode. By
soldering the resistor in the desired
position you can select following TFT
operating modes:
01
02
16-bit interface mode
8-bit interface mode
0201
Page 24 Page 25
VCC-3.3
VCC-5VVCC-5V
LED-K
VCC-3.3
VCC-3.3
P0.11
P1.23
TFT
320x
240
disp
lay
P1.22P1.21P1.20P1.19P1.18P1.17P1.16
P0.22
P0.9P0.12P0.8P0.10
P0.29P0.30P0.25P0.28
123456789
1011121314151617181920212223242526272829303132333435363738394041424344454647
LED-A1LED-A2LED-A3LED-A4IM0IM1IM2IM3RESETVSYNCHSYNCDOTCLKENABLEDB17DB16DB15DB14DB13DB12DB11DB10DB9DB8DB7DB6DB5DB4DB3DB2DB1DB0SDOSDIRDWR/SCLRSCSFMARKVCC-IOVCCVCC-IGNDXRYDXLYU
P0.21P0.20P0.19P0.18P0.17P0.16P0.15
R2810K
R2710K
R361K
P0.11
P0.10
R3712
Q3BC846
Q2BC846
Q4BC846
TFT1
MI0283QT2
R48300K
R47300K
P0.25
P0.28
100nF
100nFC36
C37
GND
GNDGNDGNDGND
GNDGND
GND
GND
GND
P0.13 IM0
VCC-3.3
VCC-3.3
R1910K
R2010K
LPC2148
P1.
27P
0.31
GN
DP
0.0
P1.
31P
0.1
P0.
2V
CC
3P
1.26
GN
DP
0.3
P0.
4P
1.25
P0.
5P
0.6
P0.
7P
1.24
VR
EF
XTA
L1X
TAL2
P1.
28G
ND
AP
0.23
RE
SE
TP
1.29
P0.
20P
0.19
P0.
18P
1.30
VC
C3
GN
DV
BAT
P0.21 P1.20P0.17P0.16P0.15P1.21VCC3GND
P0.14P1.22P0.13P0.12P0.11P1.23P0.10
P0.9P0.8
P0.22RTCX1P1.19RTCX2GNDVCCAP1.18P0.25D+D-P1.17P0.28P0.29P0.30P1.16
VCC3
(8-bit)
(16-bit)
R7NOT MOUNTED
R540
VCC-3.3
IM0
TFT MODE
D4
BAT43
Figure 8-2: Touch Screen connection schematic
Page 26 Page 27
Figure 9-2: Inserting 3.5mm headphones jack
Figure 9-1: headphones connected with mikromedia
The mikromedia for ARM features MP3 codec audio controller VS1053. This
module enables audio reproduction by using stereo headphones connected to the
system via a 3.5mm connector CN6. All functions of this module are controlled by
the microcontroller over Serial Peripheral Interface (SPI).
9. Audio Module
Page 26 Page 27
CN1
PHONEJACK
STEREOOUTPUT
C17
100nF
VCC-3.3
C24
100nF
VCC-3.3
C26
100nF
VCC-3.3
C13
100nF
VCC-1.8
C23
100nF
VCC-3.3
C25
100nF
VCC-3.3
C16
100nF
VCC-1.8
C15
100nF
VCC-1.8
C27
100nF
VCC-3.3
C14
100nF
VCC-1.8
R49
R35 27
R43 10
R44 101M
R38100K
R40100K
R41100K
R39100K
R4210
R4510
R4610
LEFT
RIGHTGBUF
VCC-1.8VCC-3.3
X312.288MHz
C32
22pF
C33
C28
1uF
C2947nF
C3010nF
C3110nF
22pF
U4
P0.18
P0.19
P1.
25
P0.
22
P0.5
GPIO
P0.6P0.4
XTA
LO
XTA
LO
LEFT
GB
UF
RIG
HT
LEFT
GB
UF
RIG
HT
XTA
L1
XTA
L1G
PIO
LIN
E2
XD
CS
IOV
DD
1V
CO
DG
ND
1X
TALO
XTA
LIIO
VD
D2
DG
ND
2D
GN
D3
DG
ND
4X
CS
CV
DD
2
AG
ND
3LE
FTAV
DD
2R
CA
PAV
DD
1G
BU
FA
GN
D2
AG
ND
1R
IGH
TAV
DD
0A
GN
D0
GPIO6GPIO7
RXGPIO5
TXSCLK
SISO
CVDD3XTESTGPIO0GPIO1
GNDGPIO4
GPIO3GPIO2DREQCVDD1IOVDD0 VS1053CVDD0DGND0XRESETMICNMICP
R49
470
R50
470 R48100K
R26100K
E110uF
E910uFC41
C37
L
LEFT
R
3.3nF
3.3nF
R49
470
R50
470 R4100K
R2
E110uF
E910uFC41
C37
L
LEFT
R
RIGHT
3.3nF
3.3nF
Figure 9-3: Audio module connecting schematic
Page 28 Page 29
LPC2148 microcontroller has integrated USB 2.0 module,
which enables you to implement USB communication
functionality of your mikromedia board. Connection with
target USB host is done over miniUSB connector which
is positioned next to the audio jack.
10. USB connection
Figure 10-1: Connecting USB
cable to programming connector
There are two SMD jumpers, or zero-ohm
resistors on board for selection of USB
communication mode. By soldering the
resistor in the desired position you can
select following USB operating modes:
USB Soft connection OFF
USB Soft connection ON
01
02
Page 28 Page 29
D5MBRS140T3
VCC-5V
R57
R560
NOT MOUNTED
ON
OFF
USB MINIB
CN7
Figure 10-2: USB module connecting schematic
Page 30 Page 31
P0.21
P1.19P1.18
P0.25
P1.17P1.16
P0.2P0.3
P0.7
P0.31
P0.23
P0.8P0.9
P0.10
P0.11
P0.12
P1.20
RL
P0.0P0.1
P0.14
AN
INT
M1X26 M1X26
VCC-3.3 VCC-3.3
RST VCC-5V
PWM
DIR
P0.29
P0.30
P0.22P0.28
P0.4
P1.25
P0.5P0.6
P1.24
P1.26
P1.23
P0.13
P1.22P1.21
P0.15P0.16
P0.17P0.18P0.19
P0.20
P1.28P1.27
11. Pads
Most microcontroller pins are available for further connectivity via two 1x26 rows of
connection pads on both sides of the mikromedia board. They are designed to perfectly
match additional shields, such as Battery Boost shield, PROTO shield and others.
Pads HDR2 Pads HDR1
Figure 11-1: Pads connecting schematic
Page 30 Page 31
12. Pinout
SPI LinesInterrupt LinesAnalog LinesPWM lines I2C Lines UART lines JTAG lines
5V RST Reset pin5V power supplyGND GND Reference GroundReference GroundP0.4 LP0.5 R
left ch.SCK0/CAP0.1/AD0.6right ch.MISO0/MAT0.1/AD0.7
P0.6 P0.7 SSEL0/PWM2/EINT2MOSI0/CAP0.2/AD1.0P0.13 P0.8 TXD1/PWM4/AD1.1DTR1/MAT1.1/AD1.4P0.22 P0.9 RXD1/PWM6/EINT3AD1.7/CAP0.0/MAT0.0P0.28 P0.21 PWM5/AD1.6/CAP1.3AD0.1/CAP0.2/MAT0.2P0.29 P0.10 RTS1/CAP1.0/AD1.2AD0.2/CAP0.3/MAT0.3P0.15 P0.12 DSR1/MAT1.0/AD1.3RI1/EINT2/AD1.5P0.16 P0.14 DCD1/EINT1/SDA1EINT0/MAT0.2/CAP0.2P0.20 P0.23 VBUSMAT1.3/SSEL1/EINT3P0.30 P0.25 AD0.4/AOUTAD0.3/EINT3/CAP0.0P0.21 P0.31 UP_LED/CONNECTPWM5/AD1.6/CAP1.3P1.22 P1.16 TRACEPKT0AD1.7/CAP0.0/MAT0.0P1.23 P1.17 TRACEPKT1PIPESTAT2P1.24 P1.18 TRACEPKT2TRACECLKP1.25 P1.19 TRACEPKT3EXTIN0P1.26 P0.11 CTS1/CAP1.1/SCL1RTCKP1.27 P1.20 TRACESYNCTDOP1.28 P0.1 RXD0/PWM3/EINT0TDIP0.17 P0.0 TXD0/PWM1CAP1.2/SCK1/MAT1.2P0.18 P0.2 SCL0/CAP0.0CAP1.3/MISO1/MAT1.3P0.19 P0.3 SDA0/MAT0.0/EINT1MAT1.2/MOSI1/CAP1.2
3.3V 3.3V 3.3V power supply3.3V power supplyGND GND Reference GroundReference Ground
Pin functions Pin functions
audio out
Page 32
13. Dimensions
2.3
8 m
m (0
.09
”)
55
.47
mm
(2.2
0”)
60
.65
mm
(2.3
8”)
80.90 mm (3.19")
73.01 mm (2.90")
3.45 mm(0.14")
2.54 mm(0.10")
36
.55
mm
(1.4
4")
2.77 mm(0.11")
Page 32
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 Mik-roElektronika, 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, di-rect 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, the Mikroelektronika logo, mikroC, mikroC PRO, mikroBasic, mikroBasic PRO, mikroPascal, mikroPascal PRO, AVRflash, PICflash, dsPICprog, 18FJprog, PSOCprog, AVRprog, 8051prog, ARMflash, EasyPIC5, EasyPIC6, BigPIC5, BigPIC6, dsPIC PRO4, Easy8051B, EasyARM, EasyAVR5, EasyAVR6, BigAVR2, EasydsPIC4A, EasyPSoC4, EasyVR Stamp LV18FJ, LV24-33A, LV32MX, PIC32MX4 MultiMedia Board, PICPLC16, PICPLC8 PICPLC4, SmartGSM/GPRS, UNI-DS 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.
© Mikroelektronika™, 2011, All Rights Reserved.
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