PIC18F27J13-I/SS Microchip Technology, PIC18F27J13-I/SS Datasheet - Page 398

PIC18F27J13-I/SS

Manufacturer Part Number

PIC18F27J13-I/SS

Description

IC PIC MCU 128KB FLASH 28SSOP

Manufacturer

Microchip Technology

Series

PIC® XLP™ 18Fr

Datasheets

1.PIC18LF24J10-ISS.pdf (32 pages)

2.PIC18F26J13-ISS.pdf (496 pages)

3.PIC18F26J13-ISS.pdf (558 pages)

4.PIC18F26J13-ISS.pdf (12 pages)

Specifications of PIC18F27J13-I/SS

Core Size

8-Bit

Program Memory Size

128KB (64K x 16)

Core Processor

PIC

Speed

48MHz

Connectivity

I²C, LIN, SPI, UART/USART

Peripherals

Brown-out Detect/Reset, POR, PWM, WDT

Number Of I /o

Program Memory Type

FLASH

Ram Size

3.8K x 8

Voltage - Supply (vcc/vdd)

2.15 V ~ 3.6 V

Data Converters

A/D 10x10b/12b

Oscillator Type

Internal

Operating Temperature

-40°C ~ 85°C

Package / Case

Controller Family/series

PIC18

Cpu Speed

48MHz

Digital Ic Case Style

SSOP

Supply Voltage Range

1.8V To 5.5V

Embedded Interface Type

I2C, SPI, USART

Rohs Compliant

Yes

Processor Series

PIC18F

Core

PIC

Data Bus Width

8 bit

Data Ram Size

4 KB

Interface Type

I2C, SPI, EUSART

Maximum Clock Frequency

48 MHz

Number Of Programmable I/os

Number Of Timers

Operating Supply Voltage

2 V to 3.6 V

Maximum Operating Temperature

+ 85 C

Mounting Style

SMD/SMT

3rd Party Development Tools

52715-96, 52716-328, 52717-734, 52712-325, EWPIC18

Development Tools By Supplier

DM164128, DM180021, DM183026-2, DV164131, MA180030, DM183022, DM183032, DV164136, MA180024

Minimum Operating Temperature

- 40 C

On-chip Adc

12 bit, 10 Channel

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

For Use With

MA180030 - BOARD DEMO PIC18F47J13 FS USBMA180029 - BOARD DEMO PIC18F47J53 FS USB

Eeprom Size

Lead Free Status / Rohs Status

Details

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PIC18F47J13 FAMILY

26.1

The CTMU works by using a fixed current source to

charge a circuit. The type of circuit depends on the type

of measurement being made. In the case of charge

measurement, the current is fixed and the amount of

time the current is applied to the circuit is fixed. The

amount of voltage read by the A/D is then a measure-

ment of the capacitance of the circuit. In the case of

time measurement, the current, as well as the capaci-

tance of the circuit, is fixed. In this case, the voltage

read by the A/D is then representative of the amount of

time elapsed from the time the current source starts

and stops charging the circuit.

If the CTMU is being used as a time delay, both capaci-

tance and current source are fixed, as well as the voltage

supplied to the comparator circuit. The delay of a signal

is determined by the amount of time it takes the voltage

to charge to the comparator threshold voltage.

26.1.1

The operation of the CTMU is based on the following

equation for charge:

More simply, the amount of charge measured in

coulombs in a circuit is defined as current in amperes

(I) multiplied by the amount of time in seconds that the

current flows (t). Charge is also defined as the

capacitance in farads (C) multiplied by the voltage of

the circuit (V). It follows that:

The CTMU module provides a constant, known current

source. The A/D Converter is used to measure (V) in

the equation, leaving two unknowns: capacitance (C)

and time (t). The above equation can be used to calcu-

late capacitance or time, by either the relationship

using the known fixed capacitance of the circuit:

or by:

using a fixed time that the current source is applied to

the circuit.

26.1.2

At the heart of the CTMU is a precision current source,

designed to provide a constant reference for measure-

ments. The level of current is user selectable across

three ranges or a total of two orders of magnitude, with

the ability to trim the output in ±2% increments

(nominal). The current range is selected by the

IRNG<1:0> bits (CTMUICON<1:0>), with a value of

‘01’ representing the lowest range.

DS39974A-page 398

CTMU Operation

THEORY OF OPERATION

CURRENT SOURCE

I t 

I = C •



C V

I t 

C V.



 V 

 I 

Preliminary

Current trim is provided by the ITRIM<5:0> bits

(CTMUICON<7:2>). These six bits allow trimming of

the current source in steps of approximately 2% per

step. Note that half of the range adjusts the current

source positively and the other half reduces the current

source. A value of ‘000000’ is the neutral position (no

change). A value of ‘100001’ is the maximum negative

adjustment (approximately -62%) and ‘011111’ is the

maximum positive adjustment (approximately +62%).

26.1.3

CTMU measurements are controlled by edge events

occurring on the module’s two input channels. Each

channel, referred to as Edge 1 and Edge 2, can be con-

figured to receive input pulses from one of the edge

input pins (CTED1 and CTED2), Timer1 or Output

Compare Module 1. The input channels are level-

sensitive, responding to the instantaneous level on the

channel rather than a transition between levels. The

inputs are selected using the EDG1SEL and EDG2SEL

bit pairs (CTMUCONL<3:2> and <6:5>).

In addition to source, each channel can be configured for

event polarity using the EDGE2POL and EDGE1POL

bits (CTMUCONL<7,4>). The input channels can also

be filtered for an edge event sequence (Edge 1 occur-

ring before Edge 2) by setting the EDGSEQEN bit

(CTMUCONH<2>).

26.1.4

The CTMUCONL register also contains two status bits:

EDG2STAT and EDG1STAT (CTMUCONL<1:0>).

Their primary function is to show if an edge response

has occurred on the corresponding channel. The

CTMU automatically sets a particular bit when an edge

response is detected on its channel. The level-sensitive

nature of the input channels also means that the status

bits become set immediately if the channel’s configura-

tion is changed and is the same as the channel’s

current state.

The module uses the edge status bits to control the cur-

rent source output to external analog modules (such as

the A/D Converter). Current is only supplied to external

modules when only one (but not both) of the status bits

is set, and shuts current off when both bits are either

set or cleared. This allows the CTMU to measure cur-

rent only during the interval between edges. After both

status bits are set, it is necessary to clear them before

another measurement is taken. Both bits should be

cleared simultaneously, if possible, to avoid re-enabling

the CTMU current source.

In addition to being set by the CTMU hardware, the

edge status bits can also be set by software. This is

also the user’s application to manually enable or

disable the current source. Setting either one (but not

both) of the bits enables the current source. Setting or

clearing both bits at once disables the source.

EDGE SELECTION AND CONTROL

EDGE STATUS

 2010 Microchip Technology Inc.

PIC18F27J13-I/SS Microchip Technology, PIC18F27J13-I/SS Datasheet - Page 398

PIC18F27J13-I/SS

Specifications of PIC18F27J13-I/SS

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