XE8801AMI027LF Semtech, XE8801AMI027LF Datasheet - Page 105

XE8801AMI027LF

Manufacturer Part Number

XE8801AMI027LF

Description

IC DAS 16BIT FLASH 8K MTP 44LQFP

Manufacturer

Semtech

Datasheet

1.XE8801AMI027LF.pdf (135 pages)

Specifications of XE8801AMI027LF

Applications

Sensing Machine

Core Processor

RISC

Program Memory Type

FLASH (22 kB)

Controller Series

XE8000

Ram Size

512 x 8

Interface

UART, USRT

Number Of I /o

Voltage - Supply

2.4 V ~ 5.5 V

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

44-LQFP

For Use With

XE8000MP - PROG BOARD AND PROSTART2 CARD

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

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Part Number

Manufacturer

Quantity

Price

Company:

BOSTOCK HK LIMITED

Part Number:

XE8801AMI027LF

Manufacturer:

Semtech

Quantity:

10 000

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16.8.3

16.8.3.1

The integral non-linearity depends on the selected gain configuration. First of all, the non-linearity of the ADC (all

PGA stages bypassed) is shown in Figure 16-8.

The different PGA stages have been designed to find the best compromise between the noise performance, the

integral non-linearity and the power consumption. To obtain this, the first stage has the best noise performance and

the third stage the best linearity performance. For large input signals (small PGA gains, i.e. up to about 50), the noise

added by the PGA is very small with respect to the input signal and the second and third stage of the PGA should be

used to get the best linearity. For small input signals (large gains, i.e. above 50), the noise level in the PGA is

important and the first stage of the PGA should be used.

The following figures give the non-linearity for different gain settings of the PGA, selecting the appropriate stage to

get the best noise and linearity performance. Figure 16-9 shows the non-linearity when the third stage is used with a

gain of 1. It is of course not very useful to use the PGA with a gain of 1 unless it is used to compensate offset. By

increasing the gain, the integral non-linearity becomes even smaller since the signal in the amplifiers reduces.

Figure 16-10 shows the non-linearity for a gain of 2. Figure 16-11 shows the non-linearity for a gain of 5. Figure

16-12 shows the non-linearity for a gain of 10. By comparing these figures to Figure 16-8, it can be seen that the

third stage of the PGA does not add significant integral non-linearity.

Figure 16-13 shows the non-linearity for a gain of 20 and Figure 16-14 shows the non-linearity for a gain of 50. In

both cases the PGA2 is used at a gain of 10 and the remaining gain is realized by the third stage. It can be seen

again that the second stage of the PGA does not add significant non-linearity.

For gains above 50, the first stage PGA1 should be selected in stead of PGA2. Although the non-linearity in the first

stage of the PGA is larger than in stage 2 and 3, the gain in stage 3 is now sufficiently high so that the non-linearity

of the first stage does become negligible as is shown in Figure 16-15 for a gain of 100. Therefor, the first stage is

preferred over the second stage since it has less noise.

Increasing the gain further up to 1000 will further increase the linearity since the signal becomes very small in the

first two stages. The signal is full scale at the output of stage 3 and as shown in Figure 16-9 to Figure 16-12, this

stage has very good linearity.

Linearity

Integral non-linearity

Figure 16-8 Integral non-linearity of the ADC (PGA disabled, reference voltage of 4.8V)

16-20

XE8801A – SX8801R

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XE8801AMI027LF Semtech, XE8801AMI027LF Datasheet - Page 105

XE8801AMI027LF

Specifications of XE8801AMI027LF

Available stocks

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