MIKROE-411 mikroElektronika, MIKROE-411 Datasheet - Page 9

MIKROE-411

Manufacturer Part Number

MIKROE-411

Description

Development Boards & Kits - PIC / DSPIC EASYPIC6 DEVELOPMENT SYSTEM

Manufacturer

mikroElektronika

Datasheet

1.MIKROE-411.pdf (28 pages)

Specifications of MIKROE-411

Rohs

yes

Product

Development Kits

Core

PIC

Interface Type

CAN, IDC10, JTAG, RS-232, USB

Operating Supply Voltage

9 V to 32 V

Data Bus Width

8 bit

Description/function

Development Board Only, Touch Screen, Pencil, DS1820, LCD, Serial Cable, GLCD are not included

Dimensions

265 mm x 220 mm

Maximum Operating Temperature

+ 125 C

Minimum Operating Temperature

- 55 C

For Use With

PIC16F887

Current page: 9 of 28
Download datasheet (7Mb)

EasyPIC6 Development System

There are two ways of programming PIC microcontrollers: Low Voltage and High Voltage programming modes. The

solely High Voltage programming mode during its operation. This mode requires voltage higher than the microcontroller’s power supply voltage

(the range between 8V to 14V, depending on the type of the microcontroller in use) to be brought to the MCLR/Vpp pin in order so that the

process of programming/debugging may be performed.

mode is enabled, the programming process is initiated by applying a logic one (1) to the PGM pin. Unlike this mode, the High Voltage programming

mode is always enabled and the programming process starts by applying a high voltage to the MCLR/Vpp pin.

All PIC microcontrollers have the Low Voltage programming mode enabled by default. In some rare cases, in order to enable the microcontroller

to be programmed in the High Voltage programming mode, it is necessary to apply a logic zero (0) to the PGM pin, which prevents the

microcontroller from entering the Low Voltage programming mode. Depending on the microcontroller in use, it is possible to select one of the

following pins RB3, RB4 and RB5 to be used as the PGM pin. Jumper J10 is used as the PGM pin selector as shown in Figure 3-3.

Various positions of jumper J10

Programmer schematic

Microcontroler is plugged

into one of the following

sockets: DIP40, DIP28

DIP18A or DIP18B.

(Default position)

The position of jumpers J8 and J9

The position of jumper J7

Jumper J10 default position

when RB3, RB4 and RB5

pins are not connected to

the PGM line.

MCLR used as the

MCLR/Vpp pin.

Build-in

MCU-PGD

MCU-PGC

MCLR

Programming lines

programmer

Multiplexer

with mikroICD

Jumper J10 position

when the PGM line

is connected to the

RB5 pin.

Microcontroller is plugged

into one of the following

sockets: DIP20, DIP14 or

DIP8.

MCLR used as an

I/O pin.

MCLR

PGC

PGD

User interface

PROG

GND

VCC

D+

D-

USB

Jumpers J8 and J9 are used for selecting the socket to receive the

programming signal. Figure 3-5 shows the position of jumpers J8

and J9 depending on DIP sockets in use.

The function of the MCLR (Master Clear) pin depends on the position

of jumper J7. When placed in the left-hand position, the MCLR pin

has default function, i.e. is used as MCLR/Vpp. Otherwise, when the

jumper is placed in the right-hand position, the MCLR pin is available

as an I/O pin.

Jumper J10 position

when the PGM line is

connected to the RB4

pin.

DATA

During programming, a multiplexer disconnects

the microcontroller pins used for programming

from the rest of the board and connects them to

the

is complete, these pins are disconnected from the

programmer and may be used as input/output

pins.

programmer. After the programming

Jumper J10 position

when the PGM line

is connected to the

RB3 pin.

programmer uses

MikroElektronika

MIKROE-411 mikroElektronika, MIKROE-411 Datasheet - Page 9

MIKROE-411

Specifications of MIKROE-411

Related parts for MIKROE-411