tmp03fruz-reel7 Analog Devices, Inc., tmp03fruz-reel7 Datasheet - Page 5

tmp03fruz-reel7

Manufacturer Part Number

tmp03fruz-reel7

Description

Serial Digital Output Thermometers

Manufacturer

Analog Devices, Inc.

Datasheet

1.TMP03FRUZ-REEL7.pdf (16 pages)

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Optimizing Counter Characteristics

Counter resolution, clock rate, and the resultant temperature

decode error that occurs using a counter scheme may be deter-

mined from the following calculations:

1. T1 is nominally 10 ms, and compared to T2 is relatively

2. We now need to calculate the maximum clock frequency we

3. Now we can calculate the temperature resolution, or quanti-

Self-Heating Effects

The temperature measurement accuracy of the TMP03 may be

degraded in some applications due to self-heating. Errors intro-

duced are from the quiescent dissipation, and power dissipated

by the digital output. The magnitude of these temperature er-

rors is dependent on the thermal conductivity of the TMP03

package, the mounting technique, and effects of airflow. Static

dissipation in the TMP03 is typically 4.5 mW operating at 5 V

insensitive to temperature changes. A useful worst-case

assumption is that T1 will never exceed 12 ms over the

specified temperature range.

T1 max = 12 ms

Substituting this value for T1 in the formula, temperature

(°C) = 235 – ([T1/T2] × 400), yields a maximum value of

T2 of 44 ms at 125°C. Rearranging the formula allows the

maximum value of T2 to be calculated at any maximum

operating temperature:

T2 (Temp) = (T1max × 400)/(235 – Temp) in seconds

can apply to the gated counter so it will not overflow during

T2 time measurement. The maximum frequency is calculated

using:

Frequency (max) = Counter Size/ (T2 at maximum

temperature)

Substituting in the equation using a 12-bit counter gives,

Fmax = 4096/44 ms

zation error, provided by the counter at the chosen clock

frequency and temperature of interest. Again, using a 12-bit

counter being clocked at 90 kHz (to allow for ~5% tempera-

ture over-range), the temperature resolution at 25°C is

calculated from:

Quantization Error ( ° C) = 400 × ([Count1/Count2] –

[Count1 – 1]/[Count2 + 1])

Quantization Error ( ° F) = 720 × ([Count1/Count2] –

[Count1 – 1]/[Count2 + 1])

where, Count1 = T1max × Frequency, and Count2 =

T2 (Temp) × Frequency. At 25°C this gives a resolution of

better than 0.3°C. Note that the temperature resolution

calculated from these equations improves as temperature

increases. Higher temperature resolution will be obtained by

employing larger counters as shown in Table I. The internal

quantization error of the TMP03 sets a theoretical minimum

resolution of approximately 0.1°C at 25°C.

Maximum

Count Available

4096

8192

16384

94 kHz.

Table I. Counter Size and Clock Frequency Effects on Quantization Error

Maximum

Temp Required

125°C

Maximum

Frequency

94 kHz

188 kHz

376 kHz

with no load. In the TO-92 package mounted in free air, this

accounts for a temperature increase due to self-heating of

For a free-standing surface-mount TSSOP package, the tem-

perature increase due to self-heating would be

In addition, power is dissipated by the digital output which is

capable of sinking 800 µA continuous (TMP04). Under full

load, the output may dissipate

For example, with T2 = 20 ms and T1 = 10 ms, the power

dissipation due to the digital output is approximately 0.32 mW

with a 0.8 mA load. In a free-standing TSSOP package, this

accounts for a temperature increase due to output self-heating

This temperature increase adds directly to that from the quies-

cent dissipation and affects the accuracy of the TMP03 relative

to the true ambient temperature. Alternatively, when the same

package has been bonded to a large plate or other thermal mass

(effectively a large heatsink) to measure its temperature, the

total self-heating error would be reduced to approximately

∆T = P

Calibration

The TMP03 and TMP04 are laser-trimmed for accuracy and

linearity during manufacture and, in most cases, no further

adjustments are required. However, some improvement in per-

formance can be gained by additional system calibration. To

perform a single-point calibration at room temperature, measure

the TMP03 output, record the actual measurement tempera-

ture, and modify the offset constant (normally 235; see the

Output Encoding section) as follows:

A more complicated 2-point calibration is also possible. This

involves measuring the TMP03 output at two temperatures,

Temp1 and Temp2, and modifying the slope constant (normally

400) as follows:

where T1 and T2 are the output high and output low times,

respectively.

Slope Constant =

∆T = P

Offset Constant = 235 + (T

∆T = P

DISS

Quantization

Error (25 C)

0.284°C

0.142°C

0.071°C

× Θ

DISS

× Θ

DISS

× θ

= (4.5 mW + 0.32 mW) × 43°C/W = 0.21°C (0.37°F)







= 0.32 mW × 240°C/W = 0.08°C (0.14°F)

T 2 @ Temp1

T1 @ Temp1

= 0.6 V

= 4.5 mW × 162°C/W = 0.73°C (1.3°F)

= 4.5 mW × 240°C/W = 1.08°C (1.9°F)

(

Temp 2 − Temp1

Quantization

Error (77 F)

0.512°F

0.256°F

0.128°F

)

(

OBSERVED

0.8 mA



 −









TMP03/TMP04

T 2 @ Temp 2

T1 @ Temp 2

)







– T

T1 + T 2

T 2

TMP03OUTPUT













)

tmp03fruz-reel7 Analog Devices, Inc., tmp03fruz-reel7 Datasheet - Page 5

tmp03fruz-reel7

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