TLC1550I_14 Datasheet, PDF(6/17 Page) Texas Instruments – Power Dissipation . . . 40 mW Max Advanced LinEPIC Single-Poly Process

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TLC1550I_14 Datasheet, PDF (6/17 Pages) Texas Instruments – Power Dissipation . . . 40 mW Max Advanced LinEPIC Single-Poly Process

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TLC1550I, TLC1550M, TLC1551I

10ÄBIT ANALOGÄTOÄDIGITAL CONVERTERS

WITH PARALLEL OUTPUTS

SLAS043G â MAY 1991 â REVISED NOVEMBER 2003

operating characteristics over recommended operating free-air temperature range with internal

clock and minimum sampling time of 4 Âµs, VDD = VREF+ = 5 V and VREFâ = 0 (unless otherwise

noted)

PARAMETER

TLC1550I

TEST CONDITIONS

TAâ

Full range

MIN TYPâ¡ MAX UNIT

Â± 0.5

Linearity error

TLC1551I

TLC1550M

See Note 3

Full range

25Â°C

Full range

Â±1

LSB

Â± 0.5

Â±1

TLC1550I

Full range

Â± 0.5

EZS

Zero-scale error

TLC1551I

TLC1550M

See Notes 2 and 4

Full range

25Â°C

Full range

Â±1

LSB

Â± 0.5

Â±1

TLC1550I

Full range

Â± 0.5

EFS

Full-scale error

TLC1551I

TLC1550M

See Notes 2 and 4

Full range

25Â°C

Full range

Â±1

LSB

Â± 0.5

Â±1

TLC1550I

Full range

Â± 0.5

Total unadjusted error

TLC1551I

TLC1550M

See Note 5

Full range

25Â°C

Â± 1 LSB

Â±1

Conversion time

fclock(external) = 4.2 MHz or

internal clock

6 Âµs

ta(D)

tv(D)

tdis(D)

Data access time after RD goes low

Data valid time after RD goes high

Disable time, delay time from RD high to high

impedance

See Figure 3

35 ns

30 ns

td(EOC) Delay time, RD low to EOC high

â Full range is â 40Â°C to 85Â°C for the TL155xI devices and â 55Â°C to 125Â°C for the TLC1550M.

â¡ All typical values are at VDD = 5 V, TA = 25Â°C.

NOTES: 2. Analog input voltages greater than that applied to REF+ convert to all 1s (1111111111), while input voltages less than that applied

to REF â convert to all 0s (0000000000). The total unadjusted error may increase as this differential voltage falls below 4.75 V.

3. Linearity error is the difference between the actual analog value at the transition between any two adjacent steps and its ideal value

after zero-scale error and full-scale error have been removed.

4. Zero-scale error is the difference between the actual mid-step value and the nominal mid-step value at specified zero scale.

Full-scale error is the difference between the actual mid-step value and the nominal mid-step value at specified full scale.

5. Total unadjusted error is the difference between the actual analog value at the transition between any two adjacent steps and its

ideal value. It includes contributions from zero-scale error, full-scale error, and linearity error.

â¢ POST OFFICE BOX 655303 DALLAS, TEXAS 75265

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