AD TMP03FT9Z

a
Serial Digital Output Thermometers
TMP03/TMP04
FEATURES
Low Cost 3-Pin Package
Modulated Serial Digital Output
Proportional to Temperature
1.5C Accuracy (typ) from –25C to +100C
Specified –40C to +100C, Operation to 150C
Power Consumption 6.5 mW Max at 5 V
Flexible Open-Collector Output on TMP03
CMOS/TTL-Compatible Output on TMP04
Low Voltage Operation (4.5 V to 7 V)
APPLICATIONS
Isolated Sensors
Environmental Control Systems
Computer Thermal Monitoring
Thermal Protection
Industrial Process Control
Power System Monitors
FUNCTIONAL BLOCK DIAGRAM
TMP03/TMP04
TEMPERATURE
SENSOR
VPTAT
DIGITAL
MODULATOR
VREF
1
2
3
DOUT
V+
GND
PACKAGE TYPES AVAILABLE
TO-92
GENERAL DESCRIPTION
The TMP03/TMP04 are monolithic temperature detectors that
generate a modulated serial digital output that varies in direct
proportion to the temperature of the device. An onboard sensor
generates a voltage precisely proportional to absolute temperature which is compared to an internal voltage reference and
input to a precision digital modulator. The ratiometric encoding
format of the serial digital output is independent of the clock drift
errors common to most serial modulation techniques such as
voltage-to-frequency converters. Overall accuracy is ± 1.5°C
(typical) from –25°C to +100°C, with excellent transducer linearity. The digital output of the TMP04 is CMOS/TTL
compatible, and is easily interfaced to the serial inputs of most
popular microprocessors. The open-collector output of the
TMP03 is capable of sinking 5 mA. The TMP03 is best suited
for systems requiring isolated circuits utilizing optocouplers or
isolation transformers.
The TMP03 and TMP04 are specified for operation at supply
voltages from 4.5 V to 7 V. Operating from 5 V, supply current
(unloaded) is less than 1.3 mA.
TMP03/TMP04
1
2
3
DOUT
V+
GND
BOTTOM VIEW
(Not to Scale)
SO-8 and RU-8 (TSSOP)
DOUT 1
V+ 2
8 NC
TMP03/
TMP04
7 NC
TOP VIEW
6 NC
(Not to Scale)
5 NC
NC 4
GND 3
NC = NO CONNECT
The TMP03/TMP04 are rated for operation over the –40°C to
+100°C temperature range in the low cost TO-92, SO-8, and
TSSOP-8 surface mount packages. Operation extends to 150°C
with reduced accuracy.
(continued on page 4)
REV. A
Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
use, nor for any infringements of patents or other rights of third parties
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700
World Wide Web Site: http://www.analog.com
Fax: 781/326-8703
© Analog Devices, Inc., 2002
TMP03/TMP04–SPECIFICATIONS
TMP03F (V+ = 5 V, –40C ≤ T ≤ 100C, unless otherwise noted.)
A
Parameter
Symbol
ACCURACY
Temperature Error
Temperature Linearity
Long-Term Stability
Nominal Mark-Space Ratio
Nominal T1 Pulsewidth
Power Supply Rejection Ratio
Conditions
–25°C < TA < +100°C1
–40°C < TA < –25°C1
T1/T2
T1
PSRR
1000 Hours at 125°C
TA = 0°C
Over Rated Supply
TA = 25°C
OUTPUTS
Output Low Voltage
Output Low Voltage
VOL
VOL
Output Low Voltage
VOL
Digital Output Capacitance
Fall Time
Device Turn-On Time
COUT
tHL
ISINK = 1.6 mA
ISINK = 5 mA
0°C < TA < 100°C
ISINK = 4 mA
–40°C < TA < 0°C
(Note 2)
See Test Load
V+
ISY
Unloaded
POWER SUPPLY
Supply Range
Supply Current
Min
Typ
Max
Unit
1.5
2.0
0.5
0.5
58.8
10
0.7
4.0
5.0
1.4
°C
°C
°C
°C
%
ms
°C/V
0.2
2
V
V
2
V
15
150
20
4.5
pF
ns
ms
0.9
7
1.3
V
mA
Typ
Max
Unit
1.0
1.5
2.0
0.5
0.5
58.8
10
0.7
3.0
4.0
5.0
°C
°C
°C
°C
°C
%
ms
°C/V
NOTES
1
Maximum deviation from output transfer function over specified temperature range.
2
Guaranteed but not tested.
Specifications subject to change without notice.
Test Load
10 kΩ to 5 V Supply, 100 pF to Ground
TMP04F
(V+ = 5 V, –40C ≤ TA ≤ 100C, unless otherwise noted.)
Parameter
Symbol
ACCURACY
Temperature Error
Temperature Linearity
Long-Term Stability
Nominal Mark-Space Ratio
Nominal T1 Pulsewidth
Power Supply Rejection Ratio
OUTPUTS
Output High Voltage
Output Low Voltage
Digital Output Capacitance
Fall Time
Rise Time
Device Turn-On Time
POWER SUPPLY
Supply Range
Supply Current
Conditions
Min
TA = 25°C
–25°C < TA < +100°C1
–40°C < TA < –25°C1
T1/T2
T1
PSRR
1000 Hours at 125°C
TA = 0°C
Over Rated Supply
TA = 25°C
VOH
VOL
COUT
tHL
tLH
IOH = 800 µA
IOL = 800 µA
(Note 2)
See Test Load
See Test Load
V+
ISY
Unloaded
1.2
V+ –0.4
0.4
15
200
160
20
4.5
0.9
7
1.3
V
V
pF
ns
ns
ms
V
mA
NOTES
1
Maximum deviation from output transfer function over specified temperature range.
2
Guaranteed but not tested.
Specifications subject to change without notice.
Test Load
100 pF to Ground
–2–
REV. A
TMP03/TMP04
ABSOLUTE MAXIMUM RATINGS*
ORDERING GUIDE
Maximum Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . 9 V
Maximum Output Current (TMP03 DOUT) . . . . . . . . . 50 mA
Maximum Output Current (TMP04 DOUT) . . . . . . . . . 10 mA
Maximum Open-Collector Output Voltage (TMP03) . . . 18 V
Operating Temperature Range . . . . . . . . . . –55°C to +150°C
Dice Junction Temperature . . . . . . . . . . . . . . . . . . . . . . 175°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +160°C
Lead Temperature (Soldering, 60 sec) . . . . . . . . . . . . . 300°C
Model
Accuracy
at 25C
Temperature
Range
Package
TMP03FT9
TMP03FS
TMP03FRU
TMP04FT9
TMP04FS
± 3.0
± 3.0
± 3.0
± 3.0
± 3.0
XIND
XIND
XIND
XIND
XIND
TO-92
SO-8
TSSOP-8
TO-92
SO-8
*CAUTION
1
Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation at or
above this specification is not implied. Exposure to the above maximum rating
conditions for extended periods may affect device reliability.
2
Digital inputs and outputs are protected, however, permanent damage may occur
on unprotected units from high-energy electrostatic fields. Keep units in conductive foam or packaging at all times until ready to use. Use proper antistatic
handling procedures.
3
Remove power before inserting or removing units from their sockets.
Package Type
TO-92 (T9)
SO-8 (S)
TSSOP (RU)
JA
1
162
1581
2401
JC
Units
120
43
43
°C/W
°C/W
°C/W
NOTE
1
ΘJA is specified for device in socket (worst case conditions).
CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the TMP03 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high-energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.
REV. A
–3–
WARNING!
ESD SENSITIVE DEVICE
TMP03/TMP04
(continued from page 1)
The TMP03 is a powerful, complete temperature measurement
system with digital output, on a single chip. The onboard temperature sensor follows in the footsteps of the TMP01 low
power programmable temperature controller, offering excellent
accuracy and linearity over the entire rated temperature range
without correction or calibration by the user.
The sensor output is digitized by a first-order sigma-delta
modulator, also known as the “charge balance” type analog-todigital converter. (See Figure 1.) This type of converter utilizes
time-domain oversampling and a high accuracy comparator to
deliver 12 bits of effective accuracy in an extremely compact
circuit.
⌺⌬ MODULATOR
INTEGRATOR
COMPARATOR
VOLTAGE REF
AND VPTAT
1-BIT
DAC
CLOCK
GENERATOR
DIGITAL
FILTER
TMP03/04
OUT
(SINGLE-BIT)
avoids major error sources common to other modulation techniques, as it is clock-independent.
Output Encoding
Accurate sampling of an analog signal requires precise spacing
of the sampling interval in order to maintain an accurate representation of the signal in the time domain. This dictates a
master clock between the digitizer and the signal processor. In
the case of compact, cost-effective data acquisition systems, the
addition of a buffered, high speed clock line can represent a
significant burden on the overall system design. Alternatively,
the addition of an onboard clock circuit with the appropriate
accuracy and drift performance to an integrated circuit can add
significant cost. The modulation and encoding techniques utilized in the TMP03 avoid this problem and allow the overall
circuit to fit into a compact, 3-pin package. To achieve this, a
simple, compact onboard clock and an oversampling digitizer
that is insensitive to sampling rate variations are used. Most
importantly, the digitized signal is encoded into a ratiometric
format in which the exact frequency of the TMP03’s clock is
irrelevant, and the effects of clock variations are effectively canceled upon decoding by the digital filter.
The output of the TMP03 is a square wave with a nominal
frequency of 35 Hz (± 20%) at 25°C. The output format is
readily decoded by the user as follows:
Figure 1. TMP03 Block Diagram Showing First-Order
Sigma-Delta Modulator
Basically, the sigma-delta modulator consists of an input sampler, a
summing network, an integrator, a comparator, and a 1-bit
DAC. Similar to the voltage-to-frequency converter, this
architecture creates in effect a negative feedback loop whose
intent is to minimize the integrator output by changing the duty
cycle of the comparator output in response to input voltage
changes. The comparator samples the output of the integrator at
a much higher rate than the input sampling frequency, called
oversampling. This spreads the quantization noise over a much
wider band than that of the input signal, improving overall noise
performance and increasing accuracy.
The modulated output of the comparator is encoded using a
circuit technique
which results in a serial digital signal with a mark-space ratio format that is easily decoded
by any microprocessor into either degrees centigrade or degrees
Fahrenheit values, and readily transmitted or modulated over a
single wire. Most importantly, this encoding method neatly
T1
T2
Figure 2. TMP03 Output Format
 400 × T1

Temperature (°C) = 235 − 
 T2 
 720 × T1

Temperature (°F) = 455 − 
 T2 
The time periods T1 (high period) and T2 (low period) are
values easily read by a microprocessor timer/counter port, with
the above calculations performed in software. Since both periods are obtained consecutively, using the same clock,
performing the division indicated in the above formulas results
in a ratiometric value that is independent of the exact frequency
of, or drift in, either the originating clock of the TMP03 or the
user’s counting clock.
–4–
REV. A
TMP03/TMP04
Table I. Counter Size and Clock Frequency Effects on Quantization Error
Maximum
Count Available
Maximum
Temp Required
Maximum
Frequency
Quantization
Error (25C)
Quantization
Error (77F)
4096
8192
16384
125°C
125°C
125°C
94 kHz
188 kHz
376 kHz
0.284°C
0.142°C
0.071°C
0.512°F
0.256°F
0.128°F
with no load. In the TO-92 package mounted in free air, this
accounts for a temperature increase due to self-heating of
Optimizing Counter Characteristics
Counter resolution, clock rate, and the resultant temperature
decode error that occurs using a counter scheme may be determined from the following calculations:
∆T = PDISS × θJA = 4.5 mW × 162°C/W = 0.73°C (1.3°F)
For a free-standing surface-mount TSSOP package, the temperature increase due to self-heating would be
1. T1 is nominally 10 ms, and compared to T2 is relatively
insensitive to temperature changes. A useful worst-case
assumption is that T1 will never exceed 12 ms over the
specified temperature range.
∆T = PDISS × θJA = 4.5 mW × 240°C/W = 1.08°C (1.9°F)
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
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 
P DISS = (0.6 V )(0.8 mA)

 T1 + T 2 
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
of
T2 (Temp) = (T1max × 400)/(235 – Temp) in seconds
2. We now need to calculate the maximum clock frequency we
can apply to the gated counter so it will not overflow during
T2 time measurement. The maximum frequency is calculated
using:
∆T = PDISS × ΘJA = 0.32 mW × 240°C/W = 0.08°C (0.14°F)
This temperature increase adds directly to that from the quiescent 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
Frequency (max) = Counter Size/ (T2 at maximum
temperature)
Substituting in the equation using a 12-bit counter gives,
Fmax = 4096/44 ms ⯝ 94 kHz.
3. Now we can calculate the temperature resolution, or quantization 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% temperature over-range), the temperature resolution at 25°C is
calculated from:
∆T = PDISS × ΘJC = (4.5 mW + 0.32 mW) × 43°C/W = 0.21°C (0.37°F)
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 performance can be gained by additional system calibration. To
perform a single-point calibration at room temperature, measure
the TMP03 output, record the actual measurement temperature, and modify the offset constant (normally 235; see the
Output Encoding section) as follows:
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.
Offset Constant = 235 + (TOBSERVED – TTMP03OUTPUT)
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:
Slope Constant =
Self-Heating Effects
The temperature measurement accuracy of the TMP03 may be
degraded in some applications due to self-heating. Errors introduced are from the quiescent dissipation, and power dissipated
by the digital output. The magnitude of these temperature errors 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
REV. A
Temp 2 − Temp1
 T1 @ Temp1   T1 @ Temp 2 

 −

 T 2 @ Temp1  T 2 @ Temp 2 
where T1 and T2 are the output high and output low times,
respectively.
–5–
TMP03/TMP04–Typical Performance Characteristics
1.05
70
OUTPUT FREQUENCY – Hz
NORMALIZED OUTPUT FREQUENCY
V+ = 5V
RLOAD = 10k
60
50
40
30
20
10
0
–75
–25
25
75
125
1.04
TA = 25C
RLOAD = 10k
1.03
1.02
1.01
1.00
0.99
0.98
0.97
4.5
175
5
5.5
6
6.5
7
7.5
SUPPLY VOLTAGE – Volts
TEMPERATURE – C
TPC 4. Normalized Output Frequency vs. Supply Voltage
TPC 1. Output Frequency vs. Temperature
45
VOLTAGE SCALE = 2V/DIV
35
T2
30
TIME – ms
SAMPLE
RUNNING:
50.0MS/s
VS = 5V
RLOAD = 10k
40
25
20
15
T1
10
(T )
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
TA = 25 C
VDD = 5V
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 1k
CH 1 RISE
500ns
CH 1 FALL
s
NO VALID EDGE
5
TIME SCALE = 1s/DIV
0
–75
–25
25
75
125
175
TEMPERATURE – C
TPC 5. TMP03 Output Rise Time at 25 °C
TPC 2. T1 and T2 Times vs. Temperature
SAMPLE
RUNNING:
50.0MS/s
(T )
TA = 25 C
VDD = 5V
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
VOLTAGE SCALE = 2V/DIV
VOLTAGE SCALE = 2V/DIV
RUNNING:
200MS/s ET
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 1k
CH 1 RISE
s
NO VALID EDGE
CH 1 FALL
209.6ns
TIME SCALE = 250ns/DIV
SAMPLE
(T )
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
TA = 125 C
VDD = 5V
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 1k
CH 1 RISE
5380ns
CH 1 FALL
s
NO VALID EDGE
TIME SCALE = 1s/DIV
TPC 3. TMP03 Output Fall Time at 25 °C
TPC 6. TMP03 Output Rise Time at 125 °C
–6–
REV. A
TMP03/TMP04
(T )
EDGE SLOPE
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
TA = 125 C
VDD = 5V
CH 1 RISE
s
NO VALID EDGE
CH 1 FALL
139.5ns
CLOAD = 100pF
RLOAD = 1k
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 0
CH 1 FALL
s
NO VALID EDGE
SAMPLE
RUNNING:
200MS/s ET
(T )
CH 1 RISE
s
NO VALID EDGE
CH 1 FALL
127.6ns
(T )
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
TA = 125 C
VDD = 5V
VOLTAGE SCALE = 2V/DIV
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 0
CH 1 RISE
110.6ns
TPC 10. TMP04 Output Rise Time at 25 °C
SAMPLE
TA = 25 C
VDD = 5V
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
TIME SCALE = 250ns/DIV
TPC 7. TMP03 Output Fall Time at 125 °C
VOLTAGE SCALE = 2V/DIV
(T )
TA = 25 C
VDD = 5V
TIME SCALE = 250ns/DIV
RUNNING:
200MS/s ET
SAMPLE
RUNNING:
200MS/s ET
SAMPLE
VOLTAGE SCALE = 2V/DIV
VOLTAGE SCALE = 2V/DIV
RUNNING:
200MS/s ET
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 0
CH 1 RISE
149.6ns
CH 1 FALL
s
NO VALID EDGE
TIME SCALE = 250ns/DIV
TIME SCALE = 250ns/DIV
TPC 8. TMP04 Output Fall Time at 25 °C
TPC 11. TMP04 Output Rise Time at 125 °C
2500
SAMPLE
TA = 25C
VS = 5V
RLOAD =
(T )
TA = 125 C
VDD = 5V
2000
CH 1 +WIDTH
s
Wfm DOES NOT
CROSS REF
FAL L TIME
CH 1 –WIDTH
s
Wfm DOES NOT
CROSS REF
CLOAD = 100pF
RLOAD = 0
TIME – ns
VOLTAGE SCALE = 2V/DIV
RUNNING:
200MS/s ET
CH 1 RISE
s
NO VALID EDGE
1500
1000
RISE TIME
CH 1 FALL
188.0ns
500
TIME SCALE = 250ns/DIV
0
0
500
1000 1500 2000 2500 3000 3500 4000 4500 5000
LOAD CAPACITANCE – pF
TPC 9. TMP04 Output Fall Time at 125 °C
REV. A
TPC 12. TMP04 Output Rise and Fall Times
vs. Capacitive Load
–7–
TMP03/TMP04
5
5
4
START-UP SUPPLY VOLTAGE – Volts
3
OUTPUT ACCURACY – C
START-UP VOLTAGE DEFINED AS OUTPUT READING
BEING WITHIN 5C OF OUTPUT AT 4.5V SUPPLY
MAXIMUM LIMIT
V+ = 5V
RLOAD = 10k
2
MEASUREMENTS IN
STIRRED OIL BATH
1
TMP03
0
TMP04
–1
–2
–3
4.5
RLOAD = 10k
4
3.5
MINIMUM LIMIT
–4
–5
–50
–25
0
50
25
TEMPERATURE – C
75
100
3
–75
125
–25
25
75
125
175
TEMPERATURE – C
TPC 16. Start-Up Voltage vs. Temperature
TPC 13. Output Accuracy vs. Temperature
1600
TYPICAL VALUES
0, T2
OUTPUT
STARTS
LOW
T1
TEMP
C
T2
ms
T1
ms
1400
–55
25
125
15
20
35
10
10
10
1200
SUPPLY CURRENT – A
V+ = 5V
RLOAD = 10k
T2
0, T1
OUTPUT
STARTS
HIGH
T2
T1
TA = 25C
NO LOAD
1000
800
600
400
200
V+
0
10
20
30
40
50
60
70
80
90
0
100
0
1
2
TIME – ms
TPC 14. Start-Up Response
3.5
POWER SUPPLY REJECTION – C/V
SUPPLY CURRENT – A
7
8
4
V+ = 5V
NO LOAD
1000
950
900
TMP03
850
TMP04
800
750
–75
6
TPC 17. Supply Current vs. Supply Voltage
1100
1050
3
5
4
SUPPLY VOLTAGE – Volts
V+ = 4.5V TO 7V
RLOAD = 10k
3
2.5
2
1.5
1
0.5
–25
25
75
125
0
–75
175
TEMPERATURE – C
–25
25
75
125
175
TEMPERATURE – C
TPC 15. Supply Current vs. Temperature
TPC 18. Power Supply Rejection vs. Temperature
–8–
REV. A
TMP03/TMP04
20
V+ = 5V DC 50mV AC
RLOAD = 10k
18
VOL = 1V
V+ = 5V
16
0.5
SINK CURRENT – mA
DEVIATION IN TEMPERATURE – C
1
NORMAL PSSR
0
14
12
10
8
–0.5
6
4
–1
1
100
10
1k
10k
100k
1M
2
–75
10M
–25
75
25
TEMPERATURE – C
FREQUENCY – Hz
TPC 19. Power Supply Rejection vs. Frequency
150
TPC 22. TMP03 Open-Collector Sink Current
vs. Temperature
105
400
100
V+ = 5V
350
300
ILOAD = 5mA
250
200
150
100
ILOAD = 1mA
75
25
~ 23 SEC (SOIC, NO SOCKET)
~ 40 SEC (TO –92, NO SOCKET)
65
60
55
50
TO –92
45
40
35
30
ILOAD = 0.5mA
–25
VS = 5V
RLOAD = 10k
70
50
0
–75
TRANSITION FROM 100C STIRRED
OIL BATH TO STILL 25C AIR
95
90
85
80
OUTPUT TEMPERATURE – C
OPEN-COLLECTOR OUTPUT VOLTAGE – mV
125
75
125
25
175
SOIC
0
25
50
75
100 125 150 175 200 225 250 275 300
TEMPERATURE – C
TIME – sec
TPC 20. TMP03 Open-Collector Output Voltage
vs. Temperature
TPC 23. Thermal Response Time in Still Air
140
OUTPUT TEMPERATURE – C
TIME CONSTANT – sec
V+ = 5V
RLOAD = 10k
100
80
60
TO –92 - WITH SOCKET
40
TO –92 - NO SOCKET
100
200
300
400
500
1.25 SEC (SOIC IN SOCKET)
2 SEC (TO –92 IN SOCKET)
TRANSITION FROM STILL 25C AIR
TO STIRRED 100C OIL BATH
600
700
0
10
20
30
40
50
60
TIME – sec
AIR VELOCITY – FPM
TPC 21. Thermal Time Constant in Forced Air
REV. A
25
0
V+ = 5V
RLOAD = 10k
TO –92
SOIC - NO SOCKET
20
0
SOIC
100
TRANSITION FROM 100C OIL BATH
TO FORCED 25C AIR
120
TPC 24. Thermal Response Time in Stirred Oil Bath
–9–
TMP03/TMP04
APPLICATIONS INFORMATION
Supply Bypassing
TMP03 Output Configurations
The TMP03 (Figure 5a) has an open-collector NPN output
which is suitable for driving a high current load, such as an
opto-isolator. Since the output source current is set by the pullup resistor, output capacitance should be minimized in TMP03
applications. Otherwise, unequal rise and fall times will skew the
pulsewidth and introduce measurement errors. The NPN transistor has a breakdown voltage of 18 V.
Precision analog products, such as the TMP03, require a wellfiltered power source. Since the TMP03 operate from a single 5
V supply, it seems convenient to simply tap into the digital logic
power supply. Unfortunately, the logic supply is often a switchmode design, which generates noise in the 20 kHz to 1 MHz
range. In addition, fast logic gates can generate glitches hundred
of millivolts in amplitude due to wiring resistance and inductance.
V+
DOUT
If possible, the TMP03 should be powered directly from the
system power supply. This arrangement, shown in Figure 3, will
isolate the analog section from the logic switching transients. Even
if a separate power supply trace is not available, however, generous supply bypassing will reduce supply-line induced errors.
Local supply bypassing consisting of a 10 µF tantalum electrolytic in parallel with a 0.1 µF ceramic capacitor is recommended
(Figure 4a).
TMP03
TMP04
a.
b.
Figure 5. TMP03 Digital Output Structure
The TMP04 has a “totem-pole” CMOS output (Figure 5b) and
provides rail-to-rail output drive for logic interfaces. The rise
and fall times of the TMP04 output are closely matched, so that
errors caused by capacitive loading are minimized. If load capacitance is large, for example when driving a long cable, an
external buffer may improve accuracy. See the “Remote Temperature Measurement” section of this data sheet for
suggestions.
TTL/CMOS
LOGIC
CIRCUITS
+10F
TANT
0.1F
TMP03/
TMP04
5V
POWER SUPPLY
Interfacing the TMP03 to Low Voltage Logic
Figure 3. Use Separate Traces to Reduce Power Supply
Noise
The TMP03’s open-collector output is ideal for driving logic
gates that operate from low supply voltages, such as 3.3 V. As
shown in Figure 6, a pull-up resistor is connected from the low
voltage logic supply (2.9 V, 3 V, etc.) to the TMP03 output.
Current through the pull-up resistor should be limited to about
1 mA, which will maintain an output LOW logic level of
<200 mV.
5V
5V
10F
0.1F
50
V+
V+
TMP03/ D
OUT
TMP04
TMP03/ D
OUT
TMP04
10F
0.1F
DOUT
3.3V
5V
GND
GND
3.3k
V+
TMP03
a.
b.
Figure 4. Recommended Supply Bypassing for the
TMP03
DOUT
TO LOW VOLTAGE
LOGIC GATE INPUT
GND
The quiescent power supply current requirement of the TMP03
is typically only 900 µA. The supply current will not change
appreciably when driving a light load (such as a CMOS gate), so
a simple RC filter can be added to further reduce power supply
noise (Figure 4b).
Figure 6. Interfacing to Low Voltage Logic
Remote Temperature Measurement
When measuring a temperature in situations where high common-mode voltages exist, an opto-isolator can be used to isolate
the output (Figure 7a). The TMP03 is recommended in this
application because its open-collector NPN transistor has a
higher current sink capability than the CMOS output of the
TMP04. To maintain the integrity of the measurement, the
opto-isolator must have relatively equal turn-on and turn-off
times. Some Darlington opto-isolators, such as the 4N32, have
a turn-off time that is much longer than their turn-on time. In
this case, the T1 time will be longer than T2, and an erroneous
reading will result. A PNP transistor can be used to provide
greater current drive to the opto-isolator (Figure 7b). An optoisolator with an integral logic gate output, such as the H11L1
from Quality Technology, can also be used (Figure 8).
–10–
REV. A
TMP03/TMP04
5V
5V
620
VLOGIC
V+
OPTO-COUPLER
4.7k
V+
TMP03
DE
DOUT
VCC
DI
DOUT
B
A
TMP04
NC
GND
GND
5V
ADM485
a.
5V
Figure 9. A Differential Line Driver for Remote Temperature Measurement
10k
270
Microcomputer Interfaces
VLOGIC
2N2907
OPTO-COUPLER
The TMP03 output is easily decoded with a microcomputer.
The microcomputer simply measures the T1 and T2 periods in
software or hardware, and then calculates the temperature using
the equation in the Output Encoding section of this data sheet.
Since the TMP03’s output is ratiometric, precise control of the
counting frequency is not required. The only timing requirements are that the clock frequency be high enough to provide
the required measurement resolution (see the Output Encoding
section for details) and that the clock source be stable. The
ratiometric output of the TMP03 is an advantage because the
microcomputer’s crystal clock frequency is often dictated by the
serial baud rate or other timing considerations.
430
V+
TMP03
4.3k
DOUT
GND
b.
Figure 7. Optically Isolating the Digital Output
5V
Pulsewidth timing is usually done with the microcomputer’s
on-chip timer. A typical example, using the 80C51, is shown in
Figure 10. This circuit requires only one input pin on the microcomputer, which highlights the efficiency of the TMP04’s
pulsewidth output format. Traditional serial input protocols,
with data line, clock and chip select, usually require three or
more I/O pins.
5V
680
V+
4.7k
TMP03
DOUT
GND
H11L1
5V
Figure 8. An Opto-Isolator with Schmitt Trigger Logic
Gate Improves Output Rise and Fall Times
V+
DOUT
The TMP03 and TMP04 are superior to analog-output transducers for measuring temperature at remote locations, because
the digital output provides better noise immunity than an analog
signal. When measuring temperature at a remote location, the
ratio of the output pulses must be maintained. To maintain the
integrity of the pulsewidth, an external buffer can be added. For
example, adding a differential line driver such as the ADM485
permits precise temperature measurements at distances up to
4000 ft. (Figure 9). The ADM485 driver and receiver skew is
only 5 ns maximum, so the TMP04 duty cycle is not degraded.
Up to 32 ADM485s can be multiplexed onto one line by providing additional decoding.
As previously mentioned, the digital output of the TMP03
provides excellent noise immunity in remote measurement applications. The user should be aware, however, that heat from an
external cable can be conducted back to the TMP03. This heat
conduction through the connecting wires can influence the
temperature of the TMP03. If large temperature differences
exist within the sensor environment, an opto-isolator, level
shifter or other thermal barrier can be used to minimize measurement errors.
REV. A
TMP04
GND
INPUT
PORT 1.0
OSC
12
TMOD REGISTER
TIMER 0 TIMER 1
TIMER 0
(16-BITS)
80C51
MICROCOMPUTER
TCON REGISTER
TIMER 0 TIMER 1
TIMER 1
(16-BITS)
Figure 10. A TMP04 Interface to the 80C51 Microcomputer
The 80C51 has two 16-bit timers. The clock source for the timers
is the crystal oscillator frequency divided by 12. Thus, a crystal
frequency of 12 MHz or greater will provide resolution of 1 µs
or less.
The 80C51 timers are controlled by two dedicated registers. The
TMOD register controls the timer mode of operation, while
TCON controls the start and stop times. Both the TMOD and
TCON registers must be set to start the timer.
–11–
TMP03/TMP04
Software for the interface is shown in Listing 1. The program
monitors the TMP04 output, and turns the counters on and off
to measure the duty cycle. The time that the output is high is mea-
sured by Timer 0, and the time that the output is low is measured
by Timer 1. When the routine finishes, the results are available
in Special Function Registers (SFRs) 08AH through 08DH.
Listing 1. An 80C51 Software Routine for the TMP04
;
; Test of a TMP04 interface to the 8051,
; using timer 0 and timer 1 to measure the duty cycle
;
; This program has three steps:
;
1. Clear the timer registers, then wait for a low-to;
high transition on input P1.0 (which is connected
;
to the output of the TMP04).
;
2. When P1.0 goes high, timer 0 starts. The program
;
then loops, testing P1.0.
;
3. When P1.0 goes low, timer 0 stops & timer 1 starts. The
;
program loops until P1.0 goes low, when timer 1 stops
;
and the TMP04’s T1 and T2 values are stored in Special
;
Function registers 8AH through 8DH (TL0 through TH1).
;
;
; Primary controls
$MOD51
$TITLE(TMP04 Interface, Using T0 and T1)
$PAGEWIDTH(80)
$DEBUG
$OBJECT
;
; Variable declarations
;
PORT1
DATA
90H
;SFR register for port 1
;TCON
DATA
88H
;timer control
;TMOD
DATA
89H
;timer mode
;TH0
DATA
8CH
;timer 0 hi byte
;TH1
DATA
8DH
;timer 1 hi byte
;TL0
DATA
8AH
;timer 0 lo byte
;TL1
DATA
8BH
;timer 1 low byte
;
;
ORG
100H
;arbitrary start
;
READ_TMP04:
MOV
A,#00
;clear the
MOV
TH0,A
; counters
MOV
TH1,A
; first
MOV
TL0,A
;
MOV
TL1,A
;
WAIT_LO:
JB
PORT1.0,WAIT_LO
;wait for TMP04 output to go low
MOV
A,#11H
;get ready to start timer0
MOV
TMOD,A
WAIT_HI:
JNB
PORT1.0,WAIT_HI
;wait for output to go high
;
;Timer 0 runs while TMP04 output is high
;
SETB
TCON.4
;start timer 0
WAITTIMER0:
JB
PORT1.0,WAITTIMER0
CLR
TCON.4
;shut off timer 0
;
;Timer 1 runs while TMP04 output is low
;
SETB
TCON.6
;start timer 1
WAITTIMER1:
JNB
PORT1.0,WAITTIMER1
CLR
TCON.6
;stop timer 1
MOV
A,#0H
;get ready to disable timers
MOV
TMOD,A
RET
END
–12–
REV. A
TMP03/TMP04
When the READ_TMP04 routine is called, the counter registers
are cleared. The program sets the counters to their 16-bit mode,
and then waits for the TMP04 output to go high. When the
input port returns a logic high level, Timer 0 starts. The timer
continues to run while the program monitors the input port.
When the TMP04 output goes low, Timer 0 stops and Timer 1
starts. Timer 1 runs until the TMP04 output goes high, at which
time the TMP04 interface is complete. When the subroutine
ends, the timer values are stored in their respective SFRs and
the TMP04’s temperature can be calculated in software.
Since the 80C51 operates asynchronously to the TMP04, there
is a delay between the TMP04 output transition and the start
of the timer. This delay can vary between 0 µs and the execution
time of the instruction that recognized the transition. The
80C51’s “jump on port.bit” instructions (JB and JNB) require
24 clock cycles for execution. With a 12 MHz clock, this produces an uncertainty of 2 µs (24 clock cycles/12 MHz) at each
transition of the TMP04 output. The worst case condition occurs
when T1 is 4 µs shorter than the actual value and T2 is 4 µs
longer. For a 25°C reading (“room temperature”), the nominal
error caused by the 2 µs delay is only about ± 0.15°C.
The TMP04 is also easily interfaced to digital signal processors
(DSPs), such as the ADSP210x series. Again, only a single I/O
pin is required for the interface (Figure 11).
V+
DOUT
TMP04
GND
FI (FLAG IN)
16-BIT DOWN
COUNTER
ADSP-210x
CLOCK
OSCILLATOR
TIMER
ENABLE
n
Figure 11. Interfacing the TMP04 to the ADSP-210x Digital
Signal Processor
The ADSP2101 only has one counter, so the interface software
differs somewhat from the 80C51 example. The lack of two
counters is not a limitation, however, because the DSP architecture provides very high execution speed. The ADSP-2101
executes one instruction for each clock cycle, versus one instruction for twelve clock cycles in the 80C51, so the ADSP-2101
actually produces a more accurate conversion while using a
lower oscillator frequency.
The timer of the ADSP2101 is implemented as a down counter.
When enabled by means of a software instruction, the counter is
decremented at the clock rate divided by a programmable prescaler. Loading the value n – 1 into the prescaler register will
divide the crystal oscillator frequency by n. For the circuit of
REV. A
A typical software routine for interfacing the TMP04 to the
ADSP2101 is shown in Listing 2. The program begins by initializing the prescaler and loading the counter with 0FFFFH. The
ADSP2101 monitors the FI flag input to establish the falling
edge of the TMP04 output, and starts the counter. When the
TMP04 output goes high, the counter is stopped. The
counter value is then subtracted from 0FFFFH to obtain the
actual number of counts, and the count is saved. Then the
counter is reloaded and runs until the TMP04 output goes low.
Finally, the TMP04 pulsewidths are converted to temperature
using the scale factor of Equation 1.
Some applications may require a hardware interface for the
TMP04. One such application could be to monitor the temperature of a high power microprocessor. The TMP04 interface
would be included as part of the system ASIC, so that the microprocessor would not be burdened with the overhead of timing
the output pulsewidths.
A typical hardware interface for the TMP04 is shown in Figure
12. The circuit measures the output pulsewidths with a resolution of ± 1 µs. The TMP04 T1 and T2 periods are measured
with two cascaded 74HC4520 8-bit counters. The counters,
accumulating clock pulses from the 1 MHz external oscillator,
have a maximum period of 65 ms.
10MHz
5V
Figure 11, therefore, loading 4 into the prescaler will divide the
10 MHz crystal oscillator by 5 and thereby decrement the counter
at a 2 MHz rate. The TMP04 output is ratiometric, of course,
so the exact clock frequency is not important.
The logic interface is straightforward. On both the rising and
falling edges of the TMP04 output, an exclusive-or gate generates a pulse. This pulse triggers one half of a 74HC4538 dual
one-shot. The pulse from the one-shot is ANDed with the
TMP04 output polarity to store the counter contents in the
appropriate output registers. The falling edge of this pulse also
triggers the second one-shot, which generates a reset pulse for
the counters. After the reset pulse, the counters will begin to
count the next TMP04 output phase.
As previously mentioned, the counters have a maximum period
of 65 ms with a 1 MHz clock input. However, the TMP04’s T1
and T2 times will never exceed 32 ms. Therefore, the most
significant bit (MSB) of counter #2 will not go high in normal operation, and can be used to warn the system that an
error condition (such as a broken connection to the TMP04)
exists.
The circuit of Figure 12 will latch and save both the T1 and T2
times simultaneously. This makes the circuit suitable for debugging or test purposes as well as for a general purpose hardware
interface. In a typical ASIC application, of course, one set of
latches could be eliminated if the latch contents, and the output
polarity, were read before the next phase reversal of the TMP04.
–13–
TMP03/TMP04
Listing 2. Software Routine for the TMP04-to-ADSP-210x Interface
;
{ ADSP-21XX Temperature Measurement Routine
Altered Registers:
Return value:
Computation time:
TEMPERAT.DSP
ax0, ay0, af, ar,
si, sr0,
my0, mr0, mr1, mr2.
ar —> temperature result in 14.2 format
2 * TMP04 output period
}
.MODULE/RAM/BOOT=0
TEMPERAT;
.ENTRY TEMPMEAS;
.CONST PRESCALER=4;
.CONST TIMFULSCALE=0Xffff;
TEMPMEAS:
si=PRESCALER;
sr0=TIMFULSCALE;
dm(0x3FFB)=si;
si=TIMFULSCALE;
dm(0x3FFC)=si;
dm(0x3FFD)=si;
imask=0x01;
TEST1:
if not fi jump TEST1;
TEST0:
if fi jump TEST0;
ena timer;
COUNT2:
if not fi jump COUNT2;
dis timer;
ay0=dm(0x3FFC);
ar=sr0-ay0;
ax0=ar;
dm(0x3FFC)=si;
ena timer;
COUNT1:
if fi jump COUNT1;
dis timer;
ay0=dm(0x3FFC);
ar=sr0-ay0;
my0=400;
mr=ar*my0(uu);
ay0=mr0;
ar=mr1; af=pass ar;
COMPUTE:
astat=0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
divq ax0; divq ax0;
ax0=0x03AC;
ar=ax0-ay0;
rts;
.ENDMOD;
{ Beginning TEMPERAT Program }
{ Entry point of this subroutine }
{
{
{
{
{
{
{
For timer prescaler }
Timer counter full scale }
Timer Prescaler set up to 5 }
CLKin=10MHz,Timer Period=32.768ms }
Timer Counter Register to 65535 }
Timer Period Register to 65535 }
Unmask Interrupt timer }
{ Check for FI=1 }
{ Check for FI=0 to locate transition }
{ Enable timer, count at a 500ns rate }
{ Check for FI=1 to stop count }
{ Save counter=T2 in ALU register }
{ Reload counter at full scale }
{ Check for FI=0 to stop count }
{ Save counter=T1 in ALU register }
{
{
{
{
{
{
mr=400*T1 }
af=MSW of dividend, ay0=LSW }
ax0=16-bit divisor }
To clear AQ flag }
Division 400*T1/T2 }
with 0.3 < T1/T2 < 0.7 }
{
{
{
{
{
Result in ay0 }
ax0=235*4 }
ar=235-400*T1/T2, result in øC }
format 14.2 }
End of the subprogram }
–14–
REV. A
TMP03/TMP04
T1 DATA (MICROSECONDS)
5V
2 5 6 9
Q1 Q2 Q3 Q4
20
11
5V
VCC
3
1
OUT
GND
LE
12 15 16 19
Q1 Q2 Q3 Q4
1
20
10
11
D5 D6 D7 D8
3 4 7 8
3
2 5 6 9
Q5 Q6 Q7 Q8
74HC373
D1 D2 D3 D4
1
2
5V
12 15 16 19
T2 DATA (MICROSECONDS)
VCC
OUT
74HC373
GND
LE
D1 D2 D3 D4
13 14 17 18
5V
1
10
D5 D6 D7 D8
3 4 7 8
2 5 6 9
Q1 Q2 Q3 Q4
Q5 Q6 Q7 Q8
20
11
VCC
12 15 16 19
74HC373
D1 D2 D3 D4
OUT
GND
LE
13 14 17 18
5V
Q5 Q6 Q7 Q8
1
10
D5 D6 D7 D8
3 4 7 8
2 5 6 9
Q1 Q2 Q3 Q4
13 14 17 18
20
11
VCC
12 15 16 19
Q5 Q6 Q7 Q8
74HC373
LE
D1 D2 D3 D4
3 4 7 8
OUT
GND
1
10
D5 D6 D7 D8
13 14 17 18
2
74HC08
4
5
6
5V
3 4 5 6 10 11 12 13 14
3 4 5 6 10 11 12 13 14
5V
Q0 Q1 Q2 Q3 EN Q0 Q1 Q2 Q3
Q0 Q1 Q2 Q3 EN Q0 Q1 Q2 Q3
1MHZ
CLOCK
16 V
CC
2
EN
1
16
74HC4520 #1
CLK
CLK GND
9
2
15
7
1
20pF
74HC86
4
6
5
5V
10k
0.1F
10F
10pF
5V
74HC4520 #2
EN
CLK CLK GND RESET RESET
RESET RESET
8
VCC
T1
1k
9
8
7
15
5V
20pF 3.9k
5V
15
14
T1
T2
T2
4
VCC 16
A
5
Q 6
B
3
7
Q
CLR
NC
GND
8
74HC4538
12
A
10
11
Q
B
13
9
Q
NC
CLR
GND
8
V+
DOUT
TMP04
GND
Figure 12. A Hardware Interface for the TMP04
Monitoring Electronic Equipment
The TMP03 are ideal for monitoring the thermal environment
within electronic equipment. For example, the surface-mounted
package will accurately reflect the exact thermal conditions which
affect nearby integrated circuits. The TO-92 package, on the
other hand, can be mounted above the surface of the board, to
measure the temperature of the air flowing over the board.
The TMP03 and TMP04 measure and convert the temperature
at the surface of their own semiconductor chip. When the TMP03
are used to measure the temperature of a nearby heat source,
the thermal impedance between the heat source and the TMP03
must be considered. Often, a thermocouple or other temperature sensor is used to measure the temperature of the source
REV. A
while the TMP03 temperature is monitored by measuring T1
and T2. Once the thermal impedance is determined, the temperature of the heat source can be inferred from the TMP03
output.
One example of using the TMP04 to monitor a high power
dissipation microprocessor or other IC is shown in Figure 13.
The TMP04, in a surface mount package, is mounted directly
beneath the microprocessor’s pin grid array (PGA) package. In
a typical application, the TMP04’s output would be connected
to an ASIC where the pulsewidth would be measured (see the
Hardware Interface section of this data sheet for a typical interface schematic). The TMP04 pulse output provides a significant
–15–
TMP03/TMP04
FAST MICROPROCESSOR, DSP, ETC., IN PGA PACKAGE
PGA SOCKET
TMP04 IN SURFACE MOUNT PACKAGE
PC BOARD
Figure 13. Monitoring the Temperature of a High Power
Microprocessor Improves System Reliability
Thermal Response Time
The time required for a temperature sensor to settle to a specified accuracy is a function of the thermal mass of, and the
thermal conductivity between, the sensor and the object being
sensed. Thermal mass is often considered equivalent to capacitance. Thermal conductivity is commonly specified using the
symbol Θ, and can be thought of as thermal resistance. It is
commonly specified in units of degrees per watt of power transferred across the thermal joint. Thus, the time required for the
TMP03 to settle to the desired accuracy is dependent on the
package selected, the thermal contact established in that particular application, and the equivalent power of the heat source.
In most applications, the settling time is probably best determined empirically. The TMP03 output operates at a nominal
frequency of 35 Hz at 25°C, so the minimum settling time resolution is 27 ms.
C00334–0–1/02(A)
advantage in this application because it produces a linear temperature output while needing only one I/O pin and without
requiring an A/D converter.
OUTLINE DIMENSIONS
Dimensions shown in inches and (mm).
3-Pin TO-92
8-Pin SOIC (SO-8)
0.1968 (5.00)
0.1890 (4.80)
0.205 (5.20)
0.175 (4.96)
0.135
(3.43)
MIN
0.1574 (4.00)
0.1497 (3.80)
0.210 (5.33)
0.170 (4.38)
0.050
(1.27)
MAX
SEATING
PLANE
5
1
4
0.2440 (6.20)
0.2284 (5.80)
PIN 1
0.0196 (0.50)
ⴛ 45ⴗ
0.0099 (0.25)
0.0500 (1.27)
BSC
0.0688 (1.75)
0.0532 (1.35)
0.0098 (0.25)
0.0040 (0.10)
0.019 (0.482)
0.016 (0.407)
0.500
(12.70)
MIN
8
8ⴗ
0.0500 (1.27)
0.0098 (0.25) 0ⴗ
0.0160 (0.41)
0.0075 (0.19)
0.0192 (0.49)
0.0138 (0.35)
SEATING
PLANE
SQUARE
8-Pin TSSOP (RU-8)
0.055 (1.39)
0.045 (1.15)
0.105 (2.66)
0.095 (2.42)
8
0.105 (2.66)
0.080 (2.42)
1
2
3
PRINTED IN U.S.A.
0.122 (3.10)
0.114 (2.90)
0.105 (2.66)
0.080 (2.42)
5
0.177 (4.50)
0.169 (4.30)
0.165 (4.19)
0.125 (3.94)
0.256 (6.50)
0.246 (6.25)
1
BOTTOM
VIEW
4
PIN 1
0.0256 (0.65)
BSC
0.006 (0.15)
0.002 (0.05)
SEATING
PLANE
–16–
0.0118 (0.30)
0.0075 (0.19)
0.0433
(1.10)
MAX
0.0079 (0.20)
0.0035 (0.090)
8ⴗ
0ⴗ
0.028 (0.70)
0.020 (0.50)
REV. A