PIC17C752 MICROCHIP [Microchip Technology], PIC17C752 Datasheet - Page 174

PIC17C752

Manufacturer Part Number

PIC17C752

Description

High-Performance 8-Bit CMOS EPROM Microcontrollers

Manufacturer

MICROCHIP [Microchip Technology]

Datasheet

1.PIC17C752.pdf (320 pages)

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16.6

The absolute accuracy speciﬁed for the A/D converter

includes the sum of all contributions for quantization

error, integral error, differential error, full scale error, off-

set error, and monotonicity. It is deﬁned as the maxi-

mum deviation from of an actual transition versus an

ideal transition for any code. The absolute error of the

A/D converter is speciﬁed at < + 1 LSb for V

(over the device’s speciﬁed operating range). How-

ever, the accuracy of the A/D converter will degrade as

For a given range of analog inputs, the output digital

code will be the same. This is due to the quantization

of the analog input to a digital code. Quantization error

is typically + 1/2 LSb and is inherent in the analog to

digital conversion process. The only way to reduce

quantization error is to increase the resolution of the

A/D converter.

Offset error measures the ﬁrst actual transition of a

code versus the ﬁrst ideal transition of a code. Offset

error shifts the entire transfer function. Offset error can

be calibrated out of a system or introduced into a sys-

tem through the interaction of the total leakage current

and source impedance at the analog input.

Gain error measures the maximum deviation of the last

actual transition and the last ideal transition adjusted

for offset error. This error appears as a change in slope

of the transfer function. The difference is gain error to

full scale error is that full scale doe not take offset error

into account. Gain error can be calibrated out in soft-

ware.

Linearity error refers to the uniformity of the code

changes. Linearity errors cannot be calibrated out of

the system. Integral non-linearity error measures the

actual code transition versus the ideal code transition

adjusted by the gain error for each code.

Differential non-linearity measures the maximum actual

code width versus the ideal code width. This measure

is unadjusted.

The maximum pin leakage current is

In systems where the device frequency is low, use of

the A/D RC clock is preferred. At moderate to high fre-

quencies, T

lator. T

when derived from T

phase clock transitions. This reduces, to a large extent,

the effects of digital switching noise. This is not possi-

ble with the RC derived clock. The loss of accuracy due

to digital switching noise can be signiﬁcant if many I/O

pins are active.

In systems where the device will enter SLEEP mode

after the start of the A/D conversion, the RC clock

source selection is required. In this mode, the digital

noise from the modules in SLEEP are stopped. This

method gives high accuracy.

DS30264A-page 174

8 s for preferred operation. This is because T

diverges from V

A/D Accuracy/Error

must not violate the minimum and should be

should be derived from the device oscil-

REF

OSC

, is kept away from on-chip

1 A.

= V

REF

Preliminary

16.7

A device reset forces all registers to their reset state.

This forces the A/D module to be turned off, and any

conversion is aborted.

The value that is in the ADRESH:ADRESL registers is

not

ADRESH:ADRESL registers will contain unknown data

after a Power-on Reset.

16.8

If the input voltage exceeds the rail values (V

by greater than 0.3V, then the accuracy of the conver-

sion is out of speciﬁcation.

An external RC ﬁlter is sometimes added for anti-alias-

ing of the input signal. The R component should be

selected to ensure that the total source impedance is

kept under the 10 k recommended speciﬁcation. Any

external components connected (via hi-impedance) to

an analog input pin (capacitor, zener diode, etc.) should

have very little leakage current at the pin.

16.9

The transfer function of the A/D converter is as follows:

the ﬁrst transition occurs when the analog input voltage

FIGURE 16-6: A/D TRANSFER FUNCTION

16.10

A good reference for the undestanding A/D converter is

the "Analog-Digital Conversion Handbook" third edi-

tion,

0-13-03-2848-0).

AIN

) equals Analog V

3FFh

3FEh

003h

002h

001h

000h

modiﬁed

published

Effects of a Reset

Connection Considerations

Transfer Function

References

for

Analog input voltage

REF

1997 Microchip Technology Inc.

/ 1024 (Figure 16-6).

Prentice

Power-on

Hall

Reset.

or V

(ISBN

The

)

PIC17C752 MICROCHIP [Microchip Technology], PIC17C752 Datasheet - Page 174

PIC17C752

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