MicroElektronika (mikroE) is a dynamic forward thinking embedded systems development tools company with its headquarters in Belgrade.
The company is unique by producing complete development tool suites; ranging from compilers, debuggers, development platforms and training materials for a wide range of microcontroller families including ARM Cortex, AVR, PIC, PIC32, dsPIC and FT90x architectures. Support is also directly available for a huge range of peripheral devices including displays, video cameras, temperature probes and multi-axis gyroscopes and accelerometers by the provision of low-cost Click Modules. Their objective is to make the transition for the developer to a new architecture as simple and efficient as possible. It achieves this by providing software library support and working examples for all supported interfaces and development systems.
MikroElektronika (mikroE) have been chosen as the development tool company of choice by many major semiconductor manufacturers as they appreciate the use of mikroE tools will speed up development of new projects. They are recognised third-party development partners of companies such as Atmel, Cypress, Microchip, STMicroelectronics, Texas Instruments and official consultants to others including NXP.
Use 64 Kbit Serial SRAM device with the development board or prototype device using the Serial RAM Board. This additional board features 23K640 Serial RAM device designed to communicate with a microcontroller via Serial Peripheral Interface (SPI). Using discrete I/O lines, the Serial RAM Board can be interfaced with a microcontroller with no built-in SPI port. It is equipped with onboard voltage translators that allow connection with systems operating at different voltage levels. The board is designed to support both 3.3V and 5V power supply. It has an LED indicator that tells about the power status of the board. Driven by low-power CMOS technology, this board works in three flexible operating modes: byte read and write, page mode (32 byte page) and sequential mode.
With these features, the SerialRAM Board is an excellent choice for depositing large amounts of temporary variables and acquisition data. It makes a great choice for increasing your microcontroller
Shake2Wake Click Board
Introduce shake functionality to the device with the Shake2Wake click board. The board features two chips from Analog Devices: an ADXL362 accelerometer that includes several activity detection modes, which is connected to an ADP195 power switch IC. This power switch IC is in turn connected to a screw terminal for controlling external devices. Upon shaking, the accelerometer sends an interrupt to the switch, which in turn, powers up the external components. The intensity and duration of shaking required for waking it up is programmable, as well as the period of inactivity, which leads to switching off the external device. Shake2Wake click can also function as a regular accelerometer, wherein the board uses the mikroBUS SPI interface for communication to the target microcontroller. This click board is designed to operate using a 3.3V power supply only. Shake2Wake click works on two main operating modes:
SHT11 Click Board
Introduce digital humidity and temperature sensing capability to your device with the SHT11 Click Board. The board employs Sensirion
SHT1X PROTO Board
Add temperature and relative humidity measurement functionality to the device using the SHT1X PROTO Board. This add-on board includes a fully calibrated SHT11 digital humidity and temperature sensor IC, wherein a unique capacitive sensor element is used for evaluating relative humidity while temperature is measured by a band-gap sensor. All that the microcontroller has to do is read out the humidity and temperature values via the two-wire digital serial interface. The two-wire serial interface along with internal voltage regulation enables simple and quick system integration. The on-board connection pads with 0.1
SIM Card Holder Board
Now easily connect your prototype board with SIM Card using the SIM Card Holder Board by MikroElektronika. This breakout board is designed for a standard 6-pin SIM card socket. When a SIM card is placed into the holder, the user can gain access to the six pins of the SIM card through the standard 0.1"(2.54mm) spaced 6-pin output of the board. Compatible with standard breadboards, the clear labelling on-board provides easy identification of each output pin. This compact, cost-effective board can be used for rapid prototyping and development.
The SmartADAPT add-on board allows user to manually redirect signal sent from a pin on the development system to a pin of another additional board or device. This board is equipped with 160 male headers from 20?
SmartADAPT 2 Board
SmartADAPT2 Board is an accessory board used to rearrange 16 I/O pins just by moving on-board jumpers in order to meet the specified needs. This board is ideal for configuring the prototype device I/O pins. This patch panel board is designed to be compatible with mikroElektronika's development systems and prototyping boards. The SmartADAPT2 Board comes with two 8-bit I/O ports to be reconfigured to aid attaching peripherals and other hardware. It has 32x16 header matrix with 16 jumpers that allow user to adjust desired input lines to appropriate output headers. The user is provided with on-board screw terminals that enable use of external power supply in place of using input headers. The output VCC pin can be configured using a jumper. The SmartADAPT2 Board supports use with 3.3V and 5V systems.
SmartADAPT MINI Board
The SmartADAPT MINI Board allows user to manually redirect signal sent from a pin on the development system to a pin of another additional board or device. This board is equipped with 160 male headers from 16x10 header matrix and 8 jumpers that aid in adjusting the input lines. By routing the input lines to specific output headers, the user can form a new, desired pinout arrangement. The SmartADAPT MINI board features two output and two input IDC10 headers compatible with mikroElektronika development and accessory boards. The SmartADAPT MINI board is designed to operate using both 3.3V and 5V systems.
Note: Pins 9 and 10 are universally reserved for VCC and GND among all mikroElektronika systems, leaving only eight output pins to be configurable.