TMP05ARTZ-REEL [ADI]
【0.5∑C Accurate PWM Temperature Sensor in 5-Lead SC-70; 【 0.5ΣC精确的PWM温度传感器采用5引脚SC- 70型号: | TMP05ARTZ-REEL |
厂家: | ADI |
描述: | 【0.5∑C Accurate PWM Temperature Sensor in 5-Lead SC-70 |
文件: | 总28页 (文件大小:983K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
± ±0.5°C AAcuratCꢀPW
TtmpturacutCStnsouCinC.-LtrdCS°-7±
C
TWꢀ±./TWꢀ±6
FUNCTIONAL BLOCK DIAGRAM
FEATURES
Modulated serial digital output, proportional to
temperature
V
DD
5
TMP05/TMP06
0.ꢀ5C accuracy at 2ꢀ5C
1.05C accuracy from 2ꢀ5C to 705C
Two grades available
Operation from −405C to +1ꢀ05C
Operation from 3 V to ꢀ.ꢀ V
TEMPERATURE
SENSOR
AVERAGING
BLOCK /
COUNTER
Σ-∆
CORE
1
OUT
REFERENCE
Power consumption 70 µW maximum at 3.3 V
CMOS/TTL-compatible output on TMP0ꢀ
Flexible open-drain output on TMP06
Small, low cost ꢀ-lead SC-70 and SOT-23 packages
OUTPUT
CONTROL
CLK AND
TIMING
GENERATION
CONV/IN
2
3
FUNC
4
APPLICATIONS
GND
Isolated sensors
Figure 1.
Environmental control systems
Computer thermal monitoring
Thermal protection
Industrial process control
Power-system monitors
The TMP05/TMP06 have three modes of operation: continu-
ously converting mode, daisy-chain mode, and one shot mode.
A three-state FUN° input determines the mode in which the
TMP05/TMP06 operate.
The °ONV/IN input pin is used to determine the rate with
which the TMP05/TMP06 measure temperature in continu-
ously converting mode and one shot mode. In daisy-chain
mode, the °ONV/IN pin operates as the input to the daisy
chain.
GENERAL DESCRIPTION
The TMP05/TMP06 are monolithic temperature sensors that
generate a modulated serial digital output (PWM), which varies
in direct proportion to the temperature of the devices. The high
period (TH) of the PWM remains static over all temperatures,
while the low period (TL) varies. The B Grade version offers a
higher temperature accuracy of ±±1° from 01° to 701° with
excellent transducer linearity. The digital output of the TMP05/
TMP06 is °MOS/TTL compatible, and is easily interfaced to
the serial inputs of most popular microprocessors. The flexible
open-drain output of the TMP06 is capable of sinking 5 mA.
PRODUCT HIGHLIGHTS
±. The TMP05/TMP06 have an on-chip temperature sensor
that allows an accurate measurement of the ambient
temperature. The measurable temperature range is –401°
to +±501°.
2. Supply voltage is 3.0 V to 5.5 V.
The TMP05/TMP06 are specified for operation at supply
voltages from 3 V to 5.5 V. Operating at 3.3 V, the supply current
is typically 370 µA. The TMP05/TMP06 are rated for operation
over the –401° to +±501° temperature range. It is not recom-
mended to operate these devices at temperatures above ±251°
for more than a total of 5% (5,000 hours) of the lifetime of the
devices. They are packaged in low cost, low area S°-70 and
SOT-23 packages.
3. Space-saving 5-lead SOT-23 and S°-70 packages.
4. Temperature accuracy is typically ±0.51°. The part needs a
decoupling capacitor to achieve this accuracy.
5. 0.0251° temperature resolution.
6. The TMP05/TMP06 feature a one shot mode that reduces
the average power consumption to ±02 µW at ± SPS.
Rev. 0
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 that may result from its use.
Specifications subject to change without notice. No license is granted by implication
or otherwise under any patent or patent rights of Analog Devices. Trademarks and
registered trademarks are the property of their respective owners.
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700
Fax: 781.326.8703
www.analog.com
© 2004 Analog Devices, Inc. All rights reserved.
TWꢀ±./TWꢀ±6C
T BLECOFC°ONTENTSC
Specifications..................................................................................... 3
Operating Modes........................................................................ ±3
TMP05 Output ........................................................................... ±6
TMP06 Output ........................................................................... ±6
Application Hints ........................................................................... ±7
Thermal Response Time ........................................................... ±7
Self-Heating Effects.................................................................... ±7
Supply Decoupling ..................................................................... ±7
Temperature Monitoring........................................................... ±8
Daisy-°hain Application........................................................... ±8
°ontinuously °onverting Application .................................... 23
Outline Dimensions....................................................................... 25
Ordering Guide .......................................................................... 25
TMP05A/TMP06A Specifications ............................................. 3
TMP05B/TMP06B Specifications .............................................. 5
Timing °haracteristics ................................................................ 7
Absolute Maximum Ratings............................................................ 8
ESD °aution.................................................................................. 8
Pin °onfiguration and Function Descriptions............................. 9
Typical Performance °haracteristics ........................................... ±0
Theory of Operation ...................................................................... ±3
°ircuit Information.................................................................... ±3
°onverter Details........................................................................ ±3
Functional Description.............................................................. ±3
REVISION HISTORY
8/04—Revision 0: Initial Version
Rev. 0 | Page 2 of 28
C
TWꢀ±./TWꢀ±6
SꢀE°IFI° TIONSC
TMP0ꢀA/TMP06A SPECIFICATIONS
All A Grade specifications apply for −401° to +±501°; VDD decoupling capacitor is a 0.± µF multilayer ceramic; TA = TMIN to TMAX, VDD
3.0 V to 5.5 V, unless otherwise noted.
=
Table 1.
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
TEMPERATURE SENSOR AND ADC
Nominal Conversion Rate (One Shot Mode)
Accuracy @ VDD = 3.3 V (3.0 V − 3.6 V)
See Table 7
TA = 0°C to 70°C, VDD = 3.0 V − 3.6 V
2
°C
3
4
51
°C
°C
°C
°C
°C/5 µs
ms
ms
TA = –40°C to +70°C, VDD = 3.0 V − 3.6 V
TA = –40°C to +125°C, VDD = 3.0 V − 3.6 V
TA = –40°C to +150°C, VDD = 3.0 V − 3.6 V
TA = 0°C to 125°C, VDD = 4.5 V − 5.5 V
Step size for every 5 µs on TL
TA = 25°C, nominal conversion rate
TA = 25°C, nominal conversion rate
See Table 7
Accuracy @ VDD = 5 V (4.5 V − 5.5 V)
Temperature Resolution
TH Pulse Width
1.5
0.025
40
TL Pulse Width
76
Quarter Period Conversion Rate
(All Operating Modes)
Accuracy @ VDD = 3.3 V (3.0 V − 3.6 V)
Accuracy @ VDD = 5 V (4.5 V − 5.5 V)
Temperature Resolution
TH Pulse Width
TL Pulse Width
Double High/Quarter Low Conversion Rate
(All Operating Modes)
1.5
1.5
0.1
10
°C
°C
°C/5 µs
ms
ms
TA = –40°C to +150°C
TA = 0°C to 125°C
Step size for every 5 µs on TL
TA = 25°C, QP conversion rate
TA = 25°C, QP conversion rate
See Table 7
19
Accuracy @ VDD = 3.3 V (3.0 V − 3.6 V)
Accuracy @ VDD = 5 V (4.5 V − 5.5 V)
Temperature Resolution
TH Pulse Width
TL Pulse Width
Long Term Drift
1.5
1.5
0.1
80
19
0.081
°C
°C
°C/5 µs
ms
ms
°C
TA = –40°C to +150°C
TA = 0°C to 125°C
Step size for every 5 µs on TL
TA = 25°C, DH/QL conversion rate
TA = 25°C, DH/QL conversion rate
Drift over 10 years, if part is operated
at 55°C
SUPPLIES
Supply Voltage
3
5.5
V
Supply Current
Normal Mode2 @ 3.3 V
Normal Mode2 @ 5.0 V
Quiescent2 @ 3.3 V
Quiescent2 @ 5.0 V
One Shot Mode @ 1 SPS
370
425
3
5.5
30.9
550
650
6
µA
µA
µA
µA
µA
Nominal conversion rate
Nominal conversion rate
Device not converting, output is high
Device not converting, output is high
Average current @ VDD = 3.3 V, nominal
conversion rate @ 25°C
10
37.38
803.33
101.9
186.9
µA
Average current @ VDD = 5.0 V, nominal
conversion rate @ 25°C
VDD = 3.3 V, continuously converting at
nominal conversion rates @ 25°C
Average power dissipated for VDD = 3.3 V,
one shot mode @ 25°C
Average power dissipated for VDD = 5.0 V,
one shot mode @ 25°C
Power Dissipation
1 SPS
µW
µW
µW
Rev. 0 | Page 3 of 28
TWꢀ±./TWꢀ±6C
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
TMP05 OUTPUT (PUSH-PULL)3
Output High Voltage, VOH
Output Low Voltage, VOL
VDD − 0.3
2
V
V
IOH = 800 µA
IOL = 800 µA
Typ VOH = 3.17 V with VDD = 3.3 V
0.4
4
Output High Current, IOUT
mA
pF
ns
ns
Ω
Pin Capacitance
10
50
50
55
Rise Time,5 tLH
Fall Time,5 tHL
RON Resistance (Low Output)
TMP06 OUTPUT (OPEN DRAIN)3
Output Low Voltage, VOL
Output Low Voltage, VOL
Pin Capacitance
High Output Leakage Current, IOH
Device Turn-On Time
Fall Time,6 tHL
RON Resistance (Low Output)
DIGITAL INPUTS3
Input Current
Input Low Voltage, VIL
Input High Voltage, VIH
Pin Capacitance
Supply and temperature dependent
0.4
1.2
V
V
IOL = 1.6 mA
IOL = 5.0 mA
10
0.1
20
30
55
pF
µA
ms
ns
Ω
5
PWMOUT = 5.5 V
Supply and temperature dependent
VIN = 0 V to VDD
1
µA
V
V
0.3 × VDD
0.7 × VDD
3
10
pF
1 It is not recommended to operate the device at temperatures above 125°C for more than a total of 5% (5,000 hours) of the lifetime of the device. Any exposure beyond
this limit affects device reliability.
2 Normal mode current relates to current during TL. TMP05/TMP06 are not converting during TH, so quiescent current relates to current during TH.
3 Guaranteed by design and characterization, not production tested.
4 It is advisable to restrict the current being pulled from the TMP05 output, because any excess currents going through the die cause self-heating. As a consequence,
false temperature readings can occur.
5 Test load circuit is 100 pF to GND.
6 Test load circuit is 100 pF to GND, 10 kΩ to 5.5 V.
Rev. 0 | Page 4 of 28
C
TWꢀ±./TWꢀ±6
TMP0ꢀB/TMP06B SPECIFICATIONS
All B Grade specifications apply for –401° to +±501°; VDD decoupling capacitor is a 0.± µF multilayer ceramic; TA = TMIN to TMAX, VDD
3.0 V to 5.5 V, unless otherwise noted.
=
Table 2.
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
TEMPERATURE SENSOR AND ADC
Nominal Conversion Rate (One Shot Mode)
Accuracy1 @ VDD = 3.3 V (3.0 V – 3.6 V)
See Table 7
TA = 25°C to 70°C, VDD = 3.0 V − 3.6 V
TA = 0°C to 70°C, VDD = 3.0 V − 3.6 V
0.5
1
1.25
°C
°C
1.5
2
2.5
32
°C
°C
°C
°C
TA = –40°C to +70°C, VDD = 3.0 V − 3.6 V
TA = –40°C to +100°C, VDD = 3.0 V − 3.6 V
TA = –40°C to +125°C, VDD = 3.0 V − 3.6 V
TA = –40°C to +150°C, VDD = 3.0 V − 3.6 V
TA = 0°C to 125°C, VDD = 4.5 V − 5.5 V
Step size for every 5 µs on TL
TA = 25°C, nominal conversion rate
TA = 25°C, nominal conversion rate
See Table 7
Accuracy @ VDD = 5.0 V (4.5 V – 5.5 V)
Temperature Resolution
TH Pulse Width
1.5
0.025
40
°C
°C/5 µs
ms
ms
TL Pulse Width
76
Quarter Period Conversion Rate
(All Operating Modes)
Accuracy @ VDD = 3.3 V (3.0 V – 3.6 V)
Accuracy @ VDD = 5.0 V (4.5 V – 5.5 V)
Temperature Resolution
TH Pulse Width
TL Pulse Width
Double High/Quarter Low Conversion Rate
(All Operating Modes)
1.5
1.5
0.1
10
°C
°C
°C/5 µs
ms
ms
TA = –40°C to +150°C
TA = 0°C to 125°C
Step size for every 5 µs on TL
TA = 25°C, QP conversion rate
TA = 25°C, QP conversion rate
See Table 7
19
Accuracy @ VDD = 3.3 V (3.0 V – 3.6 V)
Accuracy @ VDD = 5 V (4.5 V – 5.5 V)
Temperature Resolution
TH Pulse Width
TL Pulse Width
Long Term Drift
1.5
1.5
0.1
80
19
°C
°C
°C/5 µs
ms
ms
°C
TA = –40°C to +150°C
TA = 0°C to 125°C
Step size for every 5 µs on TL
TA = 25°C, DH/QL conversion rate
TA = 25°C, DH/QL conversion rate
Drift over 10 years, if part is operated at
55°C
0.081
SUPPLIES
Supply Voltage
3
5.5
V
Supply Current
Normal Mode3 @ 3.3 V
Normal Mode3 @ 5.0 V
Quiescent3 @ 3.3 V
Quiescent3 @ 5.0 V
One Shot Mode @ 1 SPS
370
425
3
5.5
30.9
550
650
6
µA
µA
µA
µA
µA
Nominal conversion rate
Nominal conversion rate
Device not converting, output is high
Device not converting, output is high
Average current @ VDD = 3.3 V, nominal
conversion rate @ 25°C
10
37.38
803.33
101.9
186.9
µA
Average current @ VDD = 5.0 V, nominal
conversion rate @ 25°C
VDD = 3.3 V, continuously converting at
nominal conversion rates @ 25°C
Average power dissipated for VDD = 3.3 V,
one shot mode @ 25°C
Average power dissipated for VDD = 5.0 V,
one shot mode @ 25°C
Power Dissipation
1 SPS
µW
µW
µW
Rev. 0 | Page 5 of 28
TWꢀ±./TWꢀ±6C
Parameter
Min
Typ
Max
Unit
Test Conditions/Comments
TMP05 OUTPUT (PUSH-PULL)4
Output High Voltage, VOH
Output Low Voltage, VOL
VDD − 0.3
2
V
V
IOH = 800 µA
IOL = 800 µA
Typ VOH = 3.17 V with VDD = 3.3 V
0.4
5
Output High Current, IOUT
mA
pF
ns
ns
Ω
Pin Capacitance
10
50
50
55
Rise Time,6 tLH
Fall Time,6 tHL
RON Resistance (Low Output)
TMP06 OUTPUT (OPEN DRAIN)4
Output Low Voltage, VOL
Output Low Voltage, VOL
Pin Capacitance
High Output Leakage Current, IOH
Device Turn-On Time
Fall Time,7 tHL
Supply and temperature dependent
0.4
1.2
V
V
pF
µA
ms
ns
IOL = 1.6 mA
IOL = 5.0 mA
10
0.1
20
30
5
PWMOUT = 5.5 V
DIGITAL INPUTS4
Input Current
1
µA
V
V
VIN = 0 V to VDD
Input Low Voltage, VIL
Input High Voltage, VIH
Pin Capacitance
0.3 × VDD
0.7 × VDD
3
10
pF
1 The accuracy specifications for 3.0 V to 3.6 V supply range are specified to 3-sigma performance. See Figure 22.
2 It is not recommended to operate the device at temperatures above 125°C for more than a total of 5% (5,000 hours) of the lifetime of the device. Any exposure beyond
this limit affects device reliability.
3 Normal mode current relates to current during TL. TMP05/TMP06 are not converting during TH, so quiescent current relates to current during TH.
4 Guaranteed by design and characterization, not production tested.
5 It is advisable to restrict the current being pulled from the TMP05 output, because any excess currents going through the die cause self-heating. As a consequence,
false temperature readings can occur.
6 Test load circuit is 100 pF to GND.
7 Test load circuit is 100 pF to GND, 10 kΩ to 5.5 V.
Rev. 0 | Page 6 of 28
C
TWꢀ±./TWꢀ±6
TIMING CHARACTERISTICS
TA = TMIN to TMAX, VDD = 3.0 V to 5.5 V, unless otherwise noted.
Guaranteed by design and characterization, not production tested.
Table 3.
Parameter
Limit
40
76
50
50
Unit
Comments
TH
TL
ms typ
ms typ
ns typ
ns typ
ns typ
µs max
PWM high time @ 25°C under nominal conversion rate
PWM low time @ 25°C under nominal conversion rate
TMP05 output rise time
TMP05 output fall time
TMP06 output fall time
1
t3
1
t4
2
t4
30
25
t5
Daisy-chain start pulse width
1 Test load circuit is 100 pF to GND.
2 Test load circuit is 100 pF to GND, 10 kΩ to 5.5 V.
T
L
T
H
t3
t4
10% 90%
90% 10%
Figure 2. PWM Output Nominal Timing Diagram (25°C)
START PULSE
t5
Figure 3. Daisy-Chain Start Timing
Rev. 0 | Page 7 of 28
TWꢀ±./TWꢀ±6C
BSOLUTECW XIWUWCR TINGSC
Table 4.
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Parameter
Rating
VDD to GND
–0.3 V to +7 V
–0.3 V to VDD + 0.3 V
10 mA
–40°C to +150°C
–65°C to +160°C
150°C
Digital Input Voltage to GND
Maximum Output Current (OUT)
Operating Temperature Range1
Storage Temperature Range
Maximum Junction Temperature, TJMAX
5-Lead SOT-23
1.0
0.9
0.8
0.7
Power Dissipation2
WMAX = (TJ max – TA3)/θJA
240°C/W
Thermal Impedance4
θJA, Junction-to-Ambient (Still Air)
5-Lead SC-70
0.6
SC-70
Power Dissipation2
WMAX = (TJ max – TA3)/θJA
0.5
Thermal Impedance4
θJA, Junction-to-Ambient
θJC, Junction-to-Case
IR Reflow Soldering
0.4
0.3
207.5°C/W
172.3°C/W
SOT-23
0.2
Peak Temperature
Time at Peak Temperature
Ramp-Up Rate
220°C (0°C/5°C)
10 s to 20 s
2°C/s to 3°C/s
–6°C/s
0.1
0
–40 –20
0
20
40
60
80
100 120 140
TEMPERATURE (°C)
Ramp-Down Rate
Figure 4. Maximum Power Dissipation vs. Temperature
1 It is not recommended to operate the device at temperatures above 125°C
for more than a total of 5% (5,000 hours) of the lifetime of the device. Any
exposure beyond this limit affects device reliability.
2 SOT-23 values relate to the package being used on a 2-layer PCB and SC-70
values relate to the package being used on a 4-layer PCB. See Figure 4 for a
plot of maximum power dissipation versus ambient temperature (TA).
3 TA = ambient temperature.
4 Junction-to-case resistance is applicable to components featuring a
preferential flow direction, for example, components mounted on a heat
sink. Junction-to-ambient resistance is more useful for air-cooled PCB
mounted components.
ESD 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 this product 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. 0 | Page 8 of 28
C
TWꢀ±./TWꢀ±6
ꢀINC°ONFIGUR TIONC NDCFUN°TIONCDES°RIꢀTIONSCC
V
1
2
3
5
OUT
CONV/IN
FUNC
DD
TMP05/
TMP06
TOP VIEW
(Not to Scale)
4
GND
Figure 5. Pin Configuration
Table 5. Pin Function Descriptions
Pin No. Mnemonic Description
1
OUT
Digital Output. Pulse-width modulated (PWM) output gives a square wave whose ratio of high to low period is
proportional to temperature.
2
CONV/IN
Digital Input. In continuously converting and one shot operating modes, a high, low, or float input determines the
temperature measurement rate. In daisy-chain operating mode, this pin is the input pin for the PWM signal from
the previous part on the daisy chain.
3
FUNC
Digital Input. A high, low, or float input on this pin gives three different modes of operation. For details, see the
Operating Modes section.
4
5
GND
VDD
Analog and Digital Ground.
Positive Supply Voltage, 3.0 V to 5.5 V. Use of a decoupling capacitor of 0.1 µF as close as possible to this pin is
strongly recommended.
Rev. 0 | Page 9 of 28
TWꢀ±./TWꢀ±6C
TYꢀI° LCꢀERFORW N°EC°H R °TERISTI°SCC
10
9
V
C
= 3.3V
DD
= 100pF
LOAD
8
7
6
0
5
4
3
2
V
= 3.3V
DD
1
1V/DIV
100ns/DIV
OUT PIN LOADED WITH 10kΩ
0
0
–50 –30 –10 10
30
50
70
90 110 130 150
TIME (ns)
TEMPERATURE (°C)
Figure 6. PWM Output Frequency vs. Temperature
Figure 9. TMP05 Output Rise Time at 25°C
8.37
8.36
8.35
8.34
8.33
8.32
8.31
8.30
8.29
V
C
= 3.3V
DD
= 100pF
LOAD
0
OUT PIN LOADED WITH 10kΩ
AMBIENT TEMPERATURE = 25°C
1V/DIV
100ns/DIV
0
3.0
3.3
3.6
3.9
4.2
4.5
4.8
5.1
5.4
TIME (ns)
SUPPLY VOLTAGE (V)
Figure 7. PWM Output Frequency vs. Supply Voltage
Figure 10. TMP05 Output Fall Time at 25°C
140
120
100
80
V
= 3.3V
DD
OUT PIN LOADED WITH 10kΩ
T
TIME
V
= 3.3V
L
DD
R
R
C
= 1k
Ω
PULLUP
= 10 k
= 100pF
Ω
LOAD
LOAD
0
60
T
TIME
H
40
20
1V/DIV
100ns/DIV
0
0
–50 –30 –10 10
30
50
70
90 110 130 150
TIME (ns)
TEMPERATURE (°C)
Figure 8. TH and TL Times vs. Temperature
Figure 11. TMP06 Output Fall Time at 25°C
Rev. 0 | Page 10 of 28
C
TWꢀ±./TWꢀ±6
2000
1800
1600
1400
1200
1000
800
1.25
1.00
0.75
0.50
0.25
0
V
= 3.3V
V
= 3.3V
DD
DD
CONTINUOUS MODE OPERATION
NOMINAL CONVERSION RATE
RISE TIME
–0.25
–0.50
–0.75
–1.00
–1.25
600
FALL TIME
400
200
0
0
1000 2000 3000 4000 5000 6000 7000 8000 9000 10000
CAPACTIVE LOAD (pF)
–40 –20
0
20
40
60
80
100
120
140
TEMPERATURE (°C)
Figure 12. TMP05 Output Rise and Fall Times vs. Capacitive Load
Figure 15. Output Accuracy vs. Temperature
250
350
300
250
200
150
100
50
V
= 3.3V
DD
V
= 3.3V
CONTINUOUS MODE OPERATION
NOMINAL CONVERSION RATE
NO LOAD ON OUT PIN
DD
I
= 5mA
LOAD
200
150
100
50
I
= 1mA
LOAD
I
= 0.5mA
LOAD
0
–50
0
–50
–25
0
25
50
75
100
125
150
–25
0
25
50
75
100
125
150
TEMPERATURE (°C)
TEMPERATURE (°C)
Figure 13. TMP06 Output Low Voltage vs. Temperature
Figure 16. Supply Current vs. Temperature
35
30
25
20
15
255
250
245
240
235
230
225
220
215
AMBIENT TEMPERATURE = 25°C
CONTINUOUS MODE OPERATION
NOMINAL CONVERSION RATE
NO LOAD ON OUT PIN
V
= 3.3V
DD
–50
–25
0
25
50
75
100
125
150
2.7
3.0
3.3
3.6
3.9
4.2
4.5
4.8
5.1
5.4
5.7
TEMPERATURE (°C)
SUPPLY VOLTAGE (V)
Figure 14. TMP06 Open Drain Sink Current vs. Temperature
Figure 17. Supply Current vs. Supply Voltage
Rev. 0 | Page 11 of 28
TWꢀ±./TWꢀ±6C
3.5
3.0
2.5
2.0
1.5
1.0
0.5
0
1.25
1.00
0.75
0.50
0.25
0
V
= 3.3V
DD
AMBIENT TEMPERATURE = 25°C
V
= 5.5V
DD
V
= 5V
DD
–40 –20
0
20
40
60
80
100 120 140
0
5
10
15
20
25
30
TEMPERATURE (°C)
LOAD CURRENT (mA)
Figure 18. Temperature Offset vs. Power Supply Variation from 3.3 V
Figure 20. TMP05 Temperature Error vs. Load Current
140
120
FINAL TEMPERATURE = 120°C
100
80
60
TEMPERATURE OF
ENVIRONMENT (30°C)
40
20
0
CHANGED HERE
0
10
20
30
40
50
60
70
TIME (Seconds)
Figure 19. Response to Thermal Shock
Rev. 0 | Page 12 of 28
C
TWꢀ±./TWꢀ±6
THEORYCOFCOꢀER TIONC
The modulated output of the comparator is encoded using a
circuit technique that results in a serial digital signal with a
mark-space ratio format. This format is easily decoded by any
microprocessor into either 1° or 1F values, and is readily
transmitted or modulated over a single wire. More importantly,
this encoding method neatly avoids major error sources
common to other modulation techniques, because it is clock-
independent.
CIRCUIT INFORMATION
The TMP05/TMP06 are monolithic temperature sensors that
generate a modulated serial digital output that varies in direct
proportion with the temperature of the device. An on-board
sensor generates a voltage precisely proportional to absolute
temperature, which is compared to an internal voltage reference
and is 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 for the A Grade is ±21° from 01° to +701°, with
excellent transducer linearity. B Grade accuracy is ±±1° from
251° to 701°. The digital output of the TMP05 is °MOS/TTL
compatible, and is easily interfaced to the serial inputs of most
popular microprocessors. The open-drain output of the TMP06
is capable of sinking 5 mA.
FUNCTIONAL DESCRIPTION
The output of the TMP05/TMP06 is a square wave with a
typical period of ±±6 ms at 251° (°ONV/IN pin is left floating).
The high period, TH, is constant, while the low period, TL, varies
with measured temperature. The output format for the nominal
conversion rate is readily decoded by the user as follows:
Temperature (1°) = 42± − (75± × (TH/TL))
(±)
The on-board temperature sensor has excellent accuracy and
linearity over the entire rated temperature range without
correction or calibration by the user.
T
T
L
H
The sensor output is digitized by a first-order Σ-∆ modulator,
also known as the charge balance type analog-to-digital
converter. This type of converter utilizes time-domain over-
sampling and a high accuracy comparator to deliver ±2 bits of
effective accuracy in an extremely compact circuit.
Figure 22. TMP05/TMP06 Output Format
The time periods TH (high period) and TL (low period) are
values easily read by a microprocessor timer/counter port, with
the above calculations performed in software. Because both
periods are obtained consecutively using the same clock,
performing the division indicated in the previous formula
results in a ratiometric value that is independent of the exact
frequency or drift of either the originating clock of the TMP05/
TMP06 or the user’s counting clock.
CONVERTER DETAILS
The Σ-∆ modulator consists of an input sampler, a summing
network, an integrator, a comparator, and a ±-bit DA°. 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, which is called
oversampling. Oversampling spreads the quantization noise
over a much wider band than that of the input signal, improving
overall noise performance and increasing accuracy.
OPERATING MODES
The user can program the TMP05/TMP06 to operate in three
different modes by configuring the FUN° pin on power-up as
either low, floating, or high.
Table 6. Operating Modes
FUNC Pin
Operating Mode
Low
One shot
Σ-∆ MODULATOR
Floating
High
Continuously converting
Daisy-chain
INTEGRATOR
COMPARATOR
VOLTAGE REF
AND VPTAT
+
+
-
Continuously Converting Mode
-
In continuously converting mode, the TMP05/TMP06 continu-
ously output a square wave representing temperature. The
frequency at which this square wave is output is determined by
the state of the °ONV/IN pin on power-up. Any change to the
state of the °ONV/IN pin after power-up is not reflected in the
parts until the TMP05/TMP06 are powered down and back up.
1-BIT
DAC
TMP05/TMP06
OUT
(SINGLE-BIT)
CLOCK
GENERATOR
DIGITAL
FILTER
Figure 21. First-Order Σ-∆ Modulator
Rev. 0 | Page 13 of 28
TWꢀ±./TWꢀ±6C
One Shot Mode
Conversion Rate
In one shot mode, the TMP05/TMP06 output one square wave
representing temperature when requested by the microcon-
troller. The microcontroller pulls the OUT pin low and then
releases it to indicate to the TMP05/TMP06 that an output is
required. The temperature measurement is output when the
OUT line is released by the microcontroller (see Figure 23).
In continuously converting and one shot modes, the state of the
°ONV/IN pin on power-up determines the rate at which the
TMP05/TMP06 measure temperature. The available conversion
rates are shown in Table 7.
Table 7. Conversion Rates
CONV/IN Pin
Conversion Rate
TH/TL (2ꢀ5C)
µ
CONTROLLER PULLS DOWN
µ
CONTROLLER RELEASES
Low
Quarter period
(TH ÷ 4, TL ÷ 4)
10/19 (ms)
OUT LINE HERE
OUT LINE HERE
Floating
High
Nominal
Double high (TH x 2)
Quarter low (TL ÷ 4)
40/76 (ms)
80/19 (ms)
TEMP MEASUREMENT
T
H
T
L
The TMP05 (push-pull output) advantage when using the high
state conversion rate (double high/quarter low) is lower power
consumption. However, the trade-off is loss of resolution on the
low time. Depending on the state of the °ONV/IN pin, two
different temperature equations must be used.
T
TIME
0
Figure 23. TMP05/TMP06 One Shot OUT Pin Signal
In the TMP05 one shot mode only, an internal resistor is
switched in series with the pull-up MOSFET. The TMP05 OUT
pin has a push-pull output configuration (see Figure 24), and,
therefore, needs a series resistor to limit the current drawn on
this pin when the user pulls it low to start a temperature
conversion. This series resistance prevents any short circuit
from VDD to GND, and, therefore, protects the TMP05 from
short-circuit damage.
The temperature equation for the low and floating states’
conversion rates is
Temperature (1°) = 42± − (75± × (TH/TL))
(2)
Table 8. Conversion Times Using Equation 2
Temperature (5C)
TL (ms)
65.2
66.6
68.1
69.7
71.4
73.1
74.9
75.9
76.8
78.8
81
83.2
85.6
88.1
90.8
93.6
96.6
99.8
103.2
106.9
110.8
Nominal Cycle Time (ms)
–40
–30
–20
–10
0
10
20
25
30
40
50
60
70
80
90
105
107
108
110
111
113
115
116
117
119
121
123
126
128
131
134
137
140
143
147
151
V+
5kΩ
OUT
TMP05
Figure 24. TMP05 One Shot Mode OUT Pin Configuration
The advantages of the one shot mode include lower average
power consumption, and the microcontroller knows that the
first low-to-high transition occurs after the microcontroller
releases the OUT pin.
100
110
120
130
140
150
Rev. 0 | Page 14 of 28
C
TWꢀ±./TWꢀ±6
The temperature equation for the high state conversion rate is
OUT
CONV/IN
TMP05/
TMP06
Temperature (1°) = 42± − (93.875 × (TH/TL))
(3)
MICRO
#1
CONV/IN
OUT
IN
Table 9. Conversion Times Using Equation 3
TMP05/
TMP06
Temperature (5C)
TL (ms)
16.3
16.7
17
17.4
17.8
18.3
18.7
19
High Cycle Time (ms)
#2
OUT
CONV/IN
–40
–30
–20
–10
0
96.2
96.6
97.03
97.42
TMP05/
TMP06
#3
OUT
CONV/IN
TMP05/
TMP06
97.84
#N
10
98.27
OUT
20
98.73
25
98.96
Figure 25. Daisy-Chain Structure
30
40
50
60
70
80
90
100
110
120
130
140
150
19.2
19.7
20.2
20.8
21.4
22
22.7
23.4
24.1
25
99.21
99.71
100.24
100.8
101.4
102.02
102.69
103.4
104.15
104.95
105.81
106.73
107.71
A second microcontroller line is needed to generate the conver-
sion start pulse on the °ONV/IN pin. The pulse width of the
start pulse should be less than 25 µs. The start pulse on the
°ONV/IN pin lets the first TMP05/TMP06 part know that it
should start a conversion and output its own temperature now.
Once the part has output its own temperature, it then outputs a
start pulse for the next part on the daisy-chain link. The pulse
width of the start pulse from each TMP05/TMP06 part is
typically ±7 µs.
25.8
26.7
27.7
Figure 26 shows the start pulse on the °ONV/IN pin of the first
device on the daisy chain and Figure 27 shows the PWM output
by this first part.
MUST GO HIGH ONLY
Daisy-Chain Mode
AFTER START PULSE HAS
BEEN OUTPUT BY LAST
TMP05/TMP06 ON DAISY CHAIN.
Setting the FUN° pin to a high state allows multiple TMP05/
TMP06s to be connected together and, therefore, allows one
input line of the microcontroller to be the sole receiver of all
temperature measurements. In this mode, the °ONV/IN pin
operates as the input of the daisy chain, and conversions take
place at the nominal conversion rate of TH/TL = 40 ms/ 76 ms
at 251°.
START
PULSE
CONVERSION
STARTS ON
THIS EDGE
<25µs
T
TIME
0
Therefore, the temperature equation for the daisy-chain mode
of operation is
Figure 26. Start Pulse at CONV/IN Pin of First TMP05/TMP06 Device
on Daisy Chain
Temperature (1°) = 42± − (75± × (TH/TL))
(4)
START
PULSE
#1 TEMP MEASUREMENT
17µs
T
TIME
0
Figure 27. Daisy-Chain Temperature Measurement
and Start Pulse Output from First TMP05/TMP06
Rev. 0 | Page 15 of 28
TWꢀ±./TWꢀ±6C
START
#1 TEMP MEASUREMENT
#2 TEMP MEASUREMENT
#N TEMP MEASUREMENT PULSE
T
TIME
0
Figure 28. Daisy-Chain Signal at Input to the Microcontroller
Before the start pulse reaches a TMP05/TMP06 part in the
daisy chain, the device acts as a buffer for the previous tempera-
ture measurement signals. Each part monitors the PWM signal
for the start pulse from the previous part. Once the part detects
the start pulse, it initiates a conversion and inserts the result at
the end of the daisy-chain PWM signal. It then inserts a start
pulse for the next part in the link. The final signal input to the
microcontroller should look like Figure 28. The input signal on
Pin 2 (IN) of the first daisy-chain device must remain low until
the last device has output its start pulse.
An internal resistor is connected in series with the pull-up
MOSFET when the TMP05 is operating in one shot mode.
V+
OUT
If the input on Pin 2 (IN) goes high and remains high, the
TMP05/TMP06 part powers down between 0.3 s and ±.2 s later.
The part, therefore, requires another start pulse to generate
another temperature measurement. Note that, to reduce power
dissipation through the part, it is recommended to keep Pin 2
(IN) at a high state when the part is not converting. If the IN
pin is at 0 V, then the OUT pin is at 0 V (because it is acting as a
buffer when not converting), and drawing current through
either the pull-up MOSFET (TMP05) or the pull-up resistor
(TMP06).
TMP05
Figure 29. TMP05 Digital Output Structure
TMP06 OUTPUT
The TMP06 has an open-drain output. Because the output
source current is set by the pull-up resistor, output capacitance
should be minimized in TMP06 applications. Otherwise,
unequal rise and fall times skew the pulse width and introduce
measurement errors.
TMP0ꢀ OUTPUT
The TMP05 has a push-pull °MOS output (Figure 29) and
provides rail-to-rail output drive for logic interfaces. The rise
and fall times of the TMP05 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 might improve accuracy.
OUT
TMP06
Figure 30. TMP06 Digital Output Structure
Rev. 0 | Page 16 of 28
C
TWꢀ±./TWꢀ±6
ꢀꢀLI° TIONCHINTSCC
THERMAL RESPONSE TIME
SUPPLY DECOUPLING
The time required for a temperature sensor to settle to a
specified accuracy is a function of the thermal mass of the
sensor 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 Q, 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 TMP05/TMP06 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 TMP05/TMP06 should be decoupled with a 0.± µF ceramic
capacitor between VDD and GND. This is particularly important,
if the TMP05/TMP06 are mounted remotely from the power
supply. Precision analog products such as the TMP05/TMP06
require a well-filtered power source. Because the TMP05/
TMP06 operate from a single supply, it might seem convenient
to simply tap into the digital logic power supply. Unfortunately,
the logic supply is often a switch-mode design, which generates
noise in the 20 kHz to ± MHz range. In addition, fast logic gates
can generate glitches hundreds of mV in amplitude due to
wiring resistance and inductance.
If possible, the TMP05/TMP06 should be powered directly
from the system power supply. This arrangement, shown in
Figure 3±, isolates the analog section from the logic switching
transients. Even if a separate power supply trace is not available,
however, generous supply bypassing reduces supply-line-
induced errors. Local supply bypassing consisting of a 0.± µF
ceramic capacitor is critical for the temperature accuracy
specifications to be achieved. This decoupling capacitor must
be placed as close as possible to the TMP05/TMP06’s VDD pin.
A recommended decoupling capacitor is Phicomp’s ±00 nF,
50 V X74.
SELF-HEATING EFFECTS
The temperature measurement accuracy of the TMP05/TMP06
might be degraded in some applications due to self-heating.
Errors introduced are from the quiescent dissipation and power
dissipated when converting, that is, during TL. The magnitude of
these temperature errors is dependent on the thermal conduc-
tivity of the TMP05/TMP06 package, the mounting technique,
and the effects of airflow. Static dissipation in the TMP05/
TMP06 is typically ±0 W operating at 3.3 V with no load. In the
5-lead S°-70 package mounted in free air, this accounts for a
temperature increase due to self-heating of
Keep the capacitor package size as small as possible, because
ESL (equivalent series inductance) increases with increasing
package size. Reducing the capacitive value below ±00 nF
increases the ESR (equivalent series resistance). Use of a
capacitor with an ESL of ± nH and an ESR of 80 mΩ is
recommended.
ΔT = PDISS × θJA = ±0 µW × 2±±.41°/W = 0.002±1° (5)
In addition, power is dissipated by the digital output, which is
capable of sinking 800 µA continuously (TMP05). Under an
800 µA load, the output can dissipate
TTL/CMOS
LOGIC
CIRCUITS
P
DISS = (0.4 V)(0.8 mA)((TL)/TH + TL))
(6)
TMP05/
TMP06
0.1µF
For example, with TL = 80 ms and TH = 40 ms, the power
dissipation due to the digital output is approximately 0.2± mW.
In a free-standing S°-70 package, this accounts for a tempera-
ture increase due to self-heating of
POWER
SUPPLY
ΔT = PDISS × θJA = 0.2± mW × 2±±.41°/W = 0.0441° (7)
Figure 31. Use Separate Traces to Reduce Power Supply Noise
This temperature increase adds directly to that from the
quiescent dissipation and affects the accuracy of the TMP05/
TMP06 relative to the true ambient temperature.
It is recommended that current dissipated through the device be
kept to a minimum, because it has a proportional effect on the
temperature error.
Rev. 0 | Page 17 of 28
TWꢀ±./TWꢀ±6C
TEMPERATURE MONITORING
DAISY-CHAIN APPLICATION
The TMP05/TMP06 are ideal for monitoring the thermal
environment within electronic equipment. For example, the
surface-mounted package accurately reflects the exact thermal
conditions that affect nearby integrated circuits.
This section provides an example of how to connect two
TMP05s in daisy-chain mode to a standard 8052 microcon-
troller core. The ADu°8±2 is the microcontroller used in the
following example and has the 8052 as its core processing
engine. Figure 32 shows how to interface to the 8052 core
device. TMP05 Program °ode Example ± shows how to
communicate from the ADu°8±2 to the two daisy-chained
TMP05s. This code can also be used with the ADu°83± or any
microprocessor running on an 8052 core.
The TMP05/TMP06 measure and convert the temperature at
the surface of their own semiconductor chip. When the TMP05/
TMP06 are used to measure the temperature of a nearby heat
source, the thermal impedance between the heat source and the
TMP05/TMP06 must be considered. Often, a thermocouple or
other temperature sensor is used to measure the temperature of
the source, while the TMP05/TMP06 temperature is monitored
by measuring TH and TL. Once the thermal impedance is deter-
mined, the temperature of the heat source can be inferred from
the TMP05/TMP06 output.
Figure 32 is a diagram of the input waveform into the ADu°8±2
from the TMP05 daisy chain, and it shows how the code’s
variables are assigned. It should be referenced when reading
TMP05 Program °ode Example ±. Application notes are
available on the Analog Devices Web site showing the TMP05
working with other types of microcontrollers.
One example of using the TMP05/TMP06’s unique properties is
in monitoring a high power dissipation microprocessor. The
TMP05/TMP06 part, in a surface-mounted package, is mounted
directly beneath the microprocessor’s pin grid array (PGA)
package. In a typical application, the TMP05/TMP06’s output is
connected to an ASI°, where the pulse width is measured. The
TMP05/TMP06 pulse output provides a significant advantage in
this application, because it produces a linear temperature output
while needing only one I/O pin and without requiring an AD°.
TIMER T0
TEMPSEGMENT = 1 TEMPSEGMENT = 2 TEMPSEGMENT = 3
STARTS
TEMP_HIGH0
TEMP_HIGH1 TEMP_HIGH2
INTO
INTO
INTO
TEMP_LOW0
TEMP_LOW1
Figure 32. Reference Diagram for Software Variables
in TMP05 Program Code Example 1
Figure 33 shows how the three devices are hardwired together.
Figure 34 to Figure 36 are flow charts for this program.
START
PULSE
V
F
DD
TMP05 (U1)
ADuC812
P3.7
V
OUT
DD
0.1µ
CONV/IN
V
DD
START
PULSE
T
(U1)
H
GND
FUNC
T
(U1)
L
T
0
TIME
V
DD
TMP05 (U2)
V
P3.2/INTO
OUT
DD
0.1µF
CONV/IN
V
DD
GND
FUNC
START
PULSE
T
(U1)
T (U2)
H
H
T
(U1)
T
(U2)
L
L
T
0
TIME
Figure 33. Typical Daisy-Chain Application Circuit
Rev. 0 | Page 18 of 28
C
TWꢀ±./TWꢀ±6
DECLARE VARIABLES
INITIALIZE TIMERS
SET-UP UART
CONVERT VARIABLES
TO FLOATS
ENABLE TIMER
INTERRUPTS
CALCULATE
TEMPERATURE
FROM U1
SEND START
PULSE
TEMP U1 =
421 – (751
× (TEMP_HIGH0/
(TEMP_LOW0 – (TEMP_HIGH1)))
START TIMER 0
CALCULATE
TEMPERATURE
FROM U2
SET-UP EDGE
TRIGGERED
(H-L) INTO
TEMP U2 =
421 – (751
× (TEMP_HIGH1/
ENABLE INTO
INTERRUPT
(TEMP_LOW1 – (TEMP_HIGH2)))
SEND TEMPERATURE
RESULTS
ENABLE GLOBAL
INTERRUPTS
OUT OF UART
Figure 35. ADuC812 Temperature Calculation Routine Flowchart
WAIT FOR
INTERRUPT
PROCESS
INTERRUPTS
WAIT FOR END
OF MEASUREMENT
CALCULATE
TEMPERATURE
AND SEND
FROM UART
Figure 34. ADuC812 Main Routine Flowchart
Rev. 0 | Page 19 of 28
TWꢀ±./TWꢀ±6C
ENTER INTERRUPT
ROUTINE
NO
CHECK IF TIMER 1
IS RUNNING
YES
START TIMER 1
COPY TIMER 1 VALUES
INTO A REGISTER
RESET TIMER 1
NO
IS TEMPSEGMENT
= 1
YE S
NO
IS TEMPSEGMENT
= 2
CALCULATE
TEMP_HIGH0
YES
RESET TIMER 0
TO ZERO
NO
IS TEMPSEGMENT
= 3
CALCULATE
TEMP_LOW0
USING TIMER 1
VALUES
YE S
CALCULATE
TEMP_HIGH1
USING TIMER 0
VALUES
CALCULATE
TEMP_LOW1
INCREMENT
TEMPSEGMENT
CALCULATE
TEMP_HIGH2
USING TIMER 0
VALUES
EXIT INTERRUPT
ROUTINE
RESET TIMER 0
TO ZERO
Figure 36. ADuC812 Interrupt Routine Flowchart
TMP05 Program Code Example 1
//=============================================================================================
// Description : This program reads the temperature from 2 daisy-chained TMP05 parts.
//
// This code runs on any standard 8052 part running at 11.0592MHz.
// If an alternative core frequency is used, the only change required is an
// adjustment of the baud rate timings.
//
// P3.2 = Daisy-chain output connected to INT0.
// P3.7 = Conversion control.
// Timer0 is used in gate mode to measure the high time.
// Timer1 is triggered on a high-to-low transition of INT0 and is used to measure
// the low time.
//=============================================================================================
Rev. 0 | Page 20 of 28
C
TWꢀ±./TWꢀ±6
#include <stdio.h>
#include <ADuC812.h>
void delay(int);
//ADuC812 SFR definitions
//Daisy_Start_Pulse = P3.7
sbit Daisy_Start_Pulse = 0xB7;
sbit P3_4 = 0xB4;
long temp_high0,temp_low0,temp_high1,temp_low1,temp_high2,th,tl; //Global variables to allow
//access during ISR.
//See Figure 32.
int timer0_count=0,timer1_count=0,tempsegment=0;
void int0 () interrupt 0
//INT0 Interrupt Service Routine
{
if (TR1 == 1)
{
th = TH1;
tl = TL1;
th = TH1;
TL1 = 0;
TH1 = 0;
}
//To avoid misreading timer
TR1=1;
Already
//Start timer1 running, if not running
if (tempsegment == 1)
{
temp_high0 = (TH0*0x100+TL0)+(timer0_count*65536); //Convert to integer
TH0=0x00;
//Reset count
TL0=0x00;
timer0_count=0;
}
if (tempsegment == 2)
{
temp_low0 = (th*0x100+tl)+(timer1_count*65536);
//Convert to integer
temp_high1 = (TH0*0x100+TL0)+(timer0_count*65536); //Convert to integer
TH0=0x00;
TL0=0x00;
//Reset count
timer0_count=0;
timer1_count=0;
}
if (tempsegment == 3)
{
temp_low1 = (th*0x100+tl)+(timer1_count*65536);
//Convert to integer
//Reset count
temp_high2 = (TH0*0x100+TL0)+(timer0_count*65536);
TH0=0x00;
TL0=0x00;
timer0_count=0;
timer1_count=0;
}
tempsegment++;
}
void timer0 () interrupt 1
{
timer0_count++;
//Keep a record of timer0 overflows
//Keep a record of timer1 overflows
}
void timer1 () interrupt 3
{
timer1_count++;
Rev. 0 | Page 21 of 28
TWꢀ±./TWꢀ±6C
}
void main(void)
{
double temp1=0,temp2=0;
double T1,T2,T3,T4,T5;
// Initialization
TMOD = 0x19;
// Timer1 in 16-bit counter mode
// Timer0 in 16-bit counter mode
// with gate on INT0. Timer0 only counts when INTO pin // is high.
ET0 = 1;
// Enable timer0 interrupts
ET1 = 1;
// Enable timer1 interrupts
// Initialize segment
tempsegment = 1;
Daisy_Start_Pulse = 0;
// Pull P3.7 low
// Start Pulse
Daisy_Start_Pulse = 1;
Daisy_Start_Pulse = 0;
// Set T0 to count the high period
TR0 = 1;
//Toggle P3.7 to give start pulse
// Start timer0 running
IT0 = 1;
// Interrupt0 edge triggered
EX0 = 1;
// Enable interrupt
EA = 1;
// Enable global interrupts
for(;;)
{
if (tempsegment == 4)
break;
}
//CONFIGURE UART
SCON = 0x52 ;
TMOD = 0x20 ;
TH1 = 0xFD ;
TR1 = 1;
// 8-bit, no parity, 1 stop bit
// Configure timer1..
// ..for 9600baud..
// ..(assuming 11.0592MHz crystal)
//Convert variables to floats for calculation
T1= temp_high0;
T2= temp_low0;
T3= temp_high1;
T4= temp_low1;
T5= temp_high2;
temp1=421-(751*(T1/(T2-T3)));
temp2=421-(751*(T3/(T4-T5)));
printf("Temp1 = %f\nTemp2 = %f\n",temp1,temp2);
//Sends temperature result out UART
// END of program
while (1);
}
// Delay routine
void delay(int length)
{
while (length >=0)
length--;
}
Rev. 0 | Page 22 of 28
C
TWꢀ±./TWꢀ±6
CONTINUOUSLY CONVERTING APPLICATION
FIRST TEMP
MEASUREMENT
SECOND TEMP
MEASUREMENT
This section provides an example of how to connect one
TMP05 in continuously converting mode to a microchip
PI°±6F876 microcontroller. Figure 37 shows how to interface to
the PI°±6F876.
TMP05 Program °ode Example 2 shows how to communicate
from the microchip device to the TMP05. This code can also be
used with other PI°s by simply changing the include file for the
part.
T
0
TIME
3.3V
PIC16F876
TMP05
V
PA.0
OUT
DD
0.1µF
CONV/IN
FUNC GND
Figure 37. Typical Daisy-Chain Application Circuit
TMP05 Program Code Example 2
//=============================================================================================
//
// Description : This program reads the temperature from a TMP05 part set up in continuously
// converting mode.
// This code was written for a PIC16F876, but can be easily configured to function with other
// PICs by simply changing the include file for the part.
//
//
//
//
//
Fosc = 4MHz
Compiled under CCS C compiler IDE version 3.4
PWM output from TMP05 connected to PortA.0 of PIC16F876
//============================================================================================
#include <16F876.h>
#device adc=8
// Insert header file for the particular PIC being used
#use delay(clock=4000000)
#fuses NOWDT,XT, PUT, NOPROTECT, BROWNOUT, LVP
//_______________________________Wait for high function_____________________________________
void wait_for_high() {
while(input(PIN_A0)) ;
while(!input(PIN_A0));
/* while high, wait for low */
/* wait for high */
}
//______________________________Wait for low function_______________________________________
void wait_for_low() {
while(input(PIN_A0));
/* wait for high */
}
//_______________________________Main begins here____________________________________________
void main(){
long int high_time,low_time,temp;
setup_adc_ports(NO_ANALOGS);
setup_adc(ADC_OFF);
setup_spi(FALSE);
setup_timer_1 ( T1_INTERNAL | T1_DIV_BY_2);
//Sets up timer to overflow after 131.07ms
Rev. 0 | Page 23 of 28
TWꢀ±./TWꢀ±6C
do{
wait_for_high();
set_timer1(0);
//Reset timer
//Reset timer
wait_for_low();
high_time = get_timer1();
set_timer1(0);
wait_for_high();
low_time = get_timer1();
temp = 421 – ((751 * high_time)/low_time));
}while (TRUE);
//Temperature equation for the high state
//conversion rate.
//Temperature value stored in temp as a long int
}
Rev. 0 | Page 24 of 28
C
TWꢀ±./TWꢀ±6
OUTLINECDIWENSIONSC
2.90 BSC
5
4
3
2.00 BSC
2.80 BSC
1.60 BSC
2
5
1
4
3
1.25 BSC
PIN 1
2.10 BSC
PIN 1
2
0.95 BSC
1.90
BSC
1.30
1.15
0.90
0.65 BSC
1.10 MAX
1.00
0.90
0.70
1.45 MAX
0.22
0.08
0.22
0.08
0.46
0.36
0.26
8°
4°
0°
10°
0.30
0.15
0.10 M
AX
0.15 MAX
5°
0°
0.50
0.30
0.60
0.45
0.30
SEATING
PLANE
SEATING
PLANE
0.10 COPLANARITY
COMPLIANT TO JEDEC STANDARDS MO-203AA
COMPLIANT TO JEDEC STANDARDS MO-178AA
Figure 38. 5-Lead Thin Shrink Small Outline Transistor Package [SC-70]
Figure 39. 5-Lead Small Outline Transistor Package [SOT-23]
(KS-5)
(RJ-5)
Dimensions shown in millimeters
Dimensions shown in millimeters
ORDERING GUIDE
Package
Option
KS-5
KS-5
KS-5
RJ-5
RJ-5
RJ-5
KS-5
KS-5
KS-5
RJ-5
RJ-5
RJ-5
KS-5
KS-5
KS-5
RJ-5
RJ-5
RJ-5
KS-5
KS-5
KS-5
RJ-5
Minimum
Temperature
Temperature Package
Description
Model
Quantities/Reel Range1
Accuracy2
2°C
2°C
2°C
2°C
2°C
2°C
1°C
1°C
1°C
1°C
1°C
1°C
2°C
2°C
2°C
2°C
2°C
2°C
1°C
1°C
1°C
1°C
1°C
1°C
Branding
T8A
T8A
T8A
T8A
T8A
T8A
T8B
T8B
T8B
T8B
T8B
TMP05AKS-500RL7
TMP05AKS-REEL
TMP05AKS-REEL7
TMP05ART-500RL7
TMP05ART-REEL
TMP05ART-REEL7
TMP05BKS-500RL7
TMP05BKS-REEL
TMP05BKS-REEL7
TMP05BRT-500RL7
TMP05BRT-REEL
TMP05BRT-REEL7
TMP05AKSZ-500RL74
TMP05AKSZ-REEL4
TMP05AKSZ-REEL74
TMP05ARTZ-500RL74
TMP05ARTZ-REEL4
TMP05ARTZ-REEL74
TMP05BKSZ-500RL74
TMP05BKSZ-REEL4
TMP05BKSZ-REEL74
TMP05BRTZ-500RL74
TMP05BRTZ-REEL4
TMP05BRTZ-REEL74
500
–40°C to +150°C
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
T8B
T8C
T8C
T8C
T8C
T8C
T8C
T8D
T8D
T8D
T8D
T8D
T8D
RJ-5
RJ-5
Rev. 0 | Page 25 of 28
TWꢀ±./TWꢀ±6C
Package
Option
KS-5
KS-5
KS-5
RJ-5
RJ-5
RJ-5
KS-5
KS-5
KS-5
RJ-5
RJ-5
RJ-5
KS-5
KS-5
KS-5
RJ-5
RJ-5
RJ-5
KS-5
KS-5
KS-5
RJ-5
Minimum
Temperature
Temperature Package
Description
Model
Quantities/Reel Range1
Accuracy2
2°C
2°C
2°C
2°C
2°C
2°C
1°C
1°C
1°C
1°C
1°C
1°C
2°C
2°C
2°C
2°C
2°C
2°C
1°C
1°C
1°C
1°C
1°C
1°C
Branding
T9A
T9A
T9A
T9A
T9A
T9A
T9B
T9B
T9B
T9B
T9B
TMP06AKS-500RL7
TMP06AKS-REEL
TMP06AKS-REEL7
TMP06ART-500RL7
TMP06ART-REEL
TMP06ART-REEL7
TMP06BKS-500RL7
TMP06BKS-REEL
TMP06BKS-REEL7
TMP06BRT-500RL7
TMP06BRT-REEL
TMP06BRT-REEL7
TMP06AKSZ-500RL74
TMP06AKSZ-REEL4
TMP06AKSZ-REEL74
TMP06ARTZ-500RL74
TMP06ARTZ-REEL4
TMP06ARTZ-REEL74
TMP06BKSZ-500RL74
TMP06BKSZ-REEL4
TMP06BKSZ-REEL74
TMP06BRTZ-500RL74
TMP06BRTZ-REEL4
TMP06BRTZ-REEL74
500
–40°C to +150°C
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
5-Lead SC-70
5-Lead SC-70
5-Lead SC-70
5-Lead SOT-233
5-Lead SOT-233
5-Lead SOT-233
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
500
10000
3000
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
–40°C to +150°C
T9B
T9C
T9C
T9C
T9C
T9C
T9C
T9D
T9D
T9D
T9D
T9D
T9D
RJ-5
RJ-5
1 It is not recommended to operate the device at temperatures above 125°C for more than a total of 5% (5,000 hours) of the lifetime of the device. Any exposure beyond
this limit affects device reliability.
2 A-Grade temperature accuracy is over the 0°C to 70°C temperature range and B-Grade temperature accuracy is over the +25°C to 70°C temperature range.
3 Consult sales for availability.
4 Z = Pb-free part.
Rev. 0 | Page 26 of 28
C
TWꢀ±./TWꢀ±6
NOTESC
Rev. 0 | Page 27 of 28
TWꢀ±./TWꢀ±6C
NOTESC
©
2004 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
D03340–0–8/04(0)
Rev. 0 | Page 28 of 28
相关型号:
TMP05BKS-500REEL7
Switch/Digital Output Temperature Sensor, DIGITAL TEMP SENSOR-SERIAL, 12BIT(s), 4Cel, RECTANGULAR, SURFACE MOUNT, MO-203AA, SC-70, 5 PIN
ADI
TMP05BKSZ-500RL7
DIGITAL TEMP SENSOR-SERIAL, 12BIT(s), 1Cel, RECTANGULAR, SURFACE MOUNT, LEAD FREE, MO-203AA, SC-70, 5 PIN
ROCHESTER
TMP05BKSZ-REEL7
DIGITAL TEMP SENSOR-SERIAL, 12BIT(s), 1Cel, RECTANGULAR, SURFACE MOUNT, LEAD FREE, MO-203AA, SC-70, 5 PIN
ROCHESTER
TMP05BRT-500RL7
DIGITAL TEMP SENSOR-SERIAL, 12BIT(s), 1Cel, RECTANGULAR, SURFACE MOUNT, MO-178AA, SOT-23, 5 PIN
ROCHESTER
©2020 ICPDF网 联系我们和版权申明