AD AD22105

a
Low Voltage, Resistor Programmable
Thermostatic Switch
AD22105
FEATURES
User-Programmable Temperature Setpoint
2.08C Setpoint Accuracy
4.08C Preset Hysteresis
Wide Supply Range (+2.7 V dc to +7.0 V dc)
Wide Temperature Range (–408C to +1508C)
Low Power Dissipation (230 mW @ 3.3 V)
FUNCTIONAL BLOCK DIAGRAM
AD22105
200kΩ
RPULL–UP
1
8
NC
OUT
2
7
VS
GND
3
6
RSET
NC
4
5
NC
APPLICATIONS
Industrial Process Control
Thermal Control Systems
CPU Monitoring (i.e., Pentium)
Computer Thermal Management Circuits
Fan Control
Handheld/Portable Electronic Equipment
GENERAL DESCRIPTION
SET–
POINT
TEMPERATURE
SENSOR
The AD22105 is designed to operate on a single power supply
voltage from +2.7 V to +7.0 V facilitating operation in battery
powered applications as well as in industrial control systems.
Because of low power dissipation (230 µW @ 3.3 V), selfheating errors are minimized and battery life is maximized.
The AD22105 is a solid state thermostatic switch. Requiring
only one external programming resistor, the AD22105 can be set
to switch accurately at any temperature in the wide operating
range of –40°C to +150°C. Using a novel circuit architecture,
the AD22105 asserts an open collector output when the ambient
temperature exceeds the user-programmed setpoint temperature.
The AD22105 has approximately 4°C of hysteresis which prevents
rapid thermal on/off cycling.
An optional internal 200 kΩ pull-up resistor is included to
facilitate driving light loads such as CMOS inputs.
Alternatively, a low power LED indicator may be driven directly.
+2.7V TO +7.0V
8
7
6
5
AD22105
RSET
TOP VIEW
1
2
3
4
OUT
Figure 1. Typical Application Circuit
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
which may result from its use. No license is granted by implication or
otherwise under any patent or patent rights of Analog Devices.
© Analog Devices, Inc., 1996
One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700
Fax: 617/326-8703
AD22105–SPECIFICATIONS (V = 3.3 V, T = +258C, R
S
A
LOAD
= internal 200 kV, unless otherwise noted)
Parameter
Symbol
Conditions
Min
TEMPERATURE ACCURACY
Ambient Setpoint Accuracy
Temperature Setpoint Accuracy
Power Supply Rejection
ACC
ACCT
PSR
–40°C ≤ TA ≤ +125°C
+2.7 V1 < VS < +7.0 V
HYSTERESIS
Hysteresis Value
HYS
OPEN COLLECTOR OUTPUT
Output Low Voltage
VOL
POWER SUPPLY
Supply Range
Supply Current, Output “LOW”
Supply Current, Output “HIGH”
VS
ISON
ISOFF
+2.7
INTERNAL PULL-UP RESISTOR
RPULL-UP
140
TURN-ON SETTLING TIME
tON
Typ
Max
Units
± 0.5
± 2.0
± 3.0
± 0.15
°C
°C
°C/V
± 0.05
°C
4.1
ISINK = 5 mA
250
200
5
400
mV
+7.0
120
90
V
µA
µA
260
kΩ
µs
NOTES
1
The AD22105 will operate at voltages as low as +2.2 V.
Specifications subject to change without notice.
39MΩ °C
RSET = ––––––––––––——— – 90.3kΩ
TSET (°C) + 281.6 °C
80
75
70
65
60
55
R SET- kΩ
50
45
40
35
30
25
20
15
10
5
0
–50
–25
0
25
50
75
100
SET POINT TEMPERATURE – °C
125
150
Figure 2. Setpoint Resistor Values
–2–
REV. 0
AD22105
ABSOLUTE MAXIMUM RATINGS*
PIN CONFIGURATION
Maximum Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . +11 V
Maximum Output Voltage (Pin 2) . . . . . . . . . . . . . . . . +11 V
Maximum Output Current (Pin 2) . . . . . . . . . . . . . . . 10 mA
Operating Temperature Range . . . . . . . . . . –50°C to +150°C
Dice Junction Temperature . . . . . . . . . . . . . . . . . . . . +160°C
Storage Temperature Range . . . . . . . . . . . . –65°C to +160°C
Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . +300°C
RPULL-UP 1
OUT 2
GND 3
Model
AD22105AR
AD22105AR-REEL7
8-Lead SOIC
8-Lead SOIC
SO-8
SO-8
PIN DESCRIPTION
Pin No.
Description
1
2
3
4
5
6
7
8
RPULL-UP, Internal 200 kΩ (Optional)
OUT
GND
No Connection
No Connection
RSET, Temperature Setpoint Resistor
VS
No Connection
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 AD22105 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
5 NC
NC = NO CONNECT
ORDERING GUIDE
Package
Option
7 VS
TOP VIEW
(Not to Scale) 6 RSET
NC 4
*Stresses above those listed under “Absolute Maximum Ratings” may cause
permanent damage to the device. This is a stress rating only and functional
operation of the device at these or any other conditions above those listed in the
operational sections of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect device reliability.
Package
Description
8 NC
AD22105
–3–
WARNING!
ESD SENSITIVE DEVICE
AD22105–Typical Performance Characteristics
4.4
4
GUARANTEED LIMIT (+)
3
4.2
HYSTERESIS – °C
ERROR – °C
2
1
0
–1
4.0
3.8
3.6
–2
3.4
–3
–4
–50
GUARANTEED LIMIT (–)
–25
0
25
50
75
TEMPERATURE – °C
100
125
3.2
–50
150
–25
0
25
50
75
TEMPERATURE – °C
100
125
150
Figure 6. Hysteresis vs. Setpoint
Figure 3. Error vs. Setpoint
2.0
0.1
±
0.3
±
0.5
±
±
1.5
+125°C
1.0
ERROR – °C
ERROR – °C/%
±
0.7
0.5
+25°C
0.0
–40°C
–0.5
–1.0
0.9
–1.5
±
1.1
–50
–2.0
–25
0
25
50
75
TEMPERATURE – °C
100
125
150
3
4
5
VS
6
7
Figure 7. Setpoint Error vs. Supply Voltage
Figure 4. Setpoint Error Due to R SET Tolerance
120
90
VS = 7V
110
80
VS = 7V
100
IS – µA
IS – µA
70
VS = 5V
VS = 5V
90
60
80
VS = 3V
VS = 3V
50
40
–50
70
–25
0
25
50
75
TEMPERATURE – °C
100
125
60
–50
150
–25
0
25
50
75
TEMPERATURE – °C
100
125
150
Figure 8. Supply Current vs. Temperature (VOUT = LOW)
Figure 5. Supply Current vs. Temperature (VOUT = HIGH)
–4–
REV. 0
AD22105
250
0.3
200
θJA – °C/W
0.4
VOUT
TA = +150°C
0.2
TA = +25°C
0.1
100
TA = –40°C
0.0
1µA
150
50
10µA
100µA
IOUT
1mA
10mA
0
400
1200
800
FLOW RATE – CFM
Figure 11. Thermal Resistance vs. Flow Rate
Figure 9. VOUT vs. IOUT (VOUT = LOW)
100
16
90
14
80
% OF FINAL VALUE
τ – sec
12
10
8
MOVING AIR
(1200 CFM)
70
60
STILL AIR
50
40
30
6
20
4
10
0
2
0
400
800
FLOW RATE – CFM
1200
10
20
30
TIME – sec
40
50
Figure 12. Thermal Response Time
Figure 10. Thermal Response vs. Flow Rate
REV. 0
0
–5–
60
AD22105
PRODUCT DESCRIPTION
The AD22105 is a single supply semiconductor thermostat
switch that utilizes a unique circuit architecture to realize the
combined functions of a temperature sensor, setpoint comparator,
and output stage all in one integrated circuit. By using one
external resistor, the AD22105 can be programmed to switch at
any temperature selected by the system designer in the range of
–40°C to +150°C. The internal comparator is designed to switch
very accurately as the ambient temperature rises past the
setpoint temperature. When the ambient temperature falls, the
comparator relaxes its output at a somewhat lower temperature
than that at which it originally switched. The difference between
the “switch” and “unswitch” temperatures, known as the hysteresis,
is designed to be nominally 4°C.
THE SETPOINT RESISTOR
The setpoint resistor is determined by the equation:
RSET =
39 MΩ °C
– 90.3 kΩ
TSET (°C)+ 281.6°C
Eq. 1
The setpoint resistor should be connected directly between the
RSET pin (Pin 6) and the GND pin (Pin 3). If a ground plane is
used, the resistor may be connected directly to this plane at the
closest available point.
The setpoint resistor, RSET, can be of nearly any resistor type,
but its initial tolerance and thermal drift will affect the accuracy
of the programmed switching temperature. For most applications,
a 1% metal-film resistor will provide the best tradeoff between
cost and accuracy. Calculations for computing an error budget
can be found in the section “Effect of Resistor Tolerance and
Thermal Drift on Setpoint Accuracy.”
Once RSET has been calculated, it may be found that the calculated value does not agree with readily available standard
resistors of the chosen tolerance. In order to achieve an RSET
value as close as possible to the calculated value, a compound
resistor can be constructed by connecting two resistors in series
or in parallel. To conserve cost, one moderately precise resistor
and one lower precision resistor can be combined. If the moderately precise resistor provides most of the necessary resistance,
the lower precision resistor can provide a fine adjustment. Consider an example where the closest standard 1% resistor has only
90% of the value required for RSET. If a 5% series resistor is
used for the remainder, then its tolerance only adds 5% of 10%
or 0.5% additional error to the combination. Likewise, the 1%
resistor only contributes 90% of 1% or 0.9% error to the combination. These two contributions are additive resulting in a total
compound resistor tolerance of 1.4%.
EFFECT OF RESISTOR TOLERANCE AND THERMAL
DRIFT ON SETPOINT ACCURACY
Figure 3 shows the typical accuracy error in setpoint temperature
as a function of the programmed setpoint temperature. This
curve assumes an ideal resistor for RSET. The graph of Figure 4
may be used to calculate additional setpoint error as a function
of resistor tolerance. Note that this curve shows additional error
beyond the initial accuracy error of the part and should be
added to the value found in the specifications table. For example,
consider using the AD22105 programmed to switch at +125°C.
Figure 4 indicates that at +125°C, the additional error is
approximately –0.2°C/% of RSET. If a 1% resistor (of exactly
correct nominal value) is chosen, then the additional error could
be –0.2°C/% × 1% or –0.2°C. If the closest standard resistor
value is 0.6% away from the calculated value, then the total
error would be 0.6% for the nominal value and 1% for the
tolerance or (1.006) × (1.10) or 1.01606 (about 1.6%). This
could lead to an additional setpoint error as high as 0.32°C.
For additional accuracy considerations, the thermal drift of the
setpoint resistor can be taken into account. For example, consider that the drift of the metal film resistor is 100 ppm/°C.
Since this drift is usually referred to +25°C, the setpoint resistor
can be in error by an additional 100 ppm/°C × (125°C – 25°C) or
1%. Using a setpoint temperature of 125°C as discussed above,
this error source would add an additional –0.2°C (for positive drift)
making the overall setpoint error potentially –0.52°C higher than
the original accuracy error.
Initial tolerance and thermal drift effects of the setpoint resistor
can be combined and calculated by using the following
equation:
RMAX = RNOM ×(1+ ε)× (1+ T C ×(T SET – 25°C))
where:
R MAX is the worst case value that the setpoint resistor can be at
TSET,
R NOM is the standard resistor with a value closest to the desired
RSET,
ε
is the 25°C tolerance of the chosen resistor (usually 1%,
5%, or 10%),
TC
is the temperature coefficient of the available resistor,
TSET
is the desired setpoint temperature.
Once calculated, RMAX may be compared to the desired RSET
from Equation 1. Continuing the example from above, the
required value of RSET at a TSET of 125°C is 5.566 kΩ. If the
nearest standard resistor value is 5.600 kΩ, then its worst case
maximum value at 125°C could be 5.713 kΩ. Again this is
+2.6% higher than RSET leading to a total additional error of
–0.52°C beyond that given by the specifications table.
THE HYSTERESIS AND SELF-HEATING
The actual value of the hysteresis generally has a minor
dependence on the programmed setpoint temperature as shown
in Figure 6. Furthermore, the hysteresis can be affected by selfheating if the device is driving a heavy load. For example, if the
device is driving a load of 5 mA at an output voltage (given by
Figure 9) of 250 mV, then the additional power dissipation
would be approximately 1.25 mW. With a θJA of 190°C/W in
free air the internal die temperature could be 0.24°C higher
than ambient leading to an increase of 0.24°C in hysteresis. In
the presence of a heat sink or turbulent environment, the
additional hysteresis will be less.
–6–
REV. 0
AD22105
OUTPUT SECTION
Response of the AD22105 internal die temperature to abrupt
changes in ambient temperatures can be modeled by a single
time constant exponential function. Figure 11 shows typical
response plots for moving and still air. The time constant, τ
(time to reach 63.2% of the final value), is dependent on θ JA and
the thermal capacities of the chip and the package. Table I lists
the effective τ for moving and still air. Copper printed circuit
board connections were neglected in the analysis; however, they
will sink or conduct heat directly through the AD22105’s solder
plated copper leads. When faster response is required, a thermally conductive grease or glue between the AD22105 and the
surface temperature being measured should be used.
The output of the AD22105 is the collector of an NPN transistor.
When the ambient temperature of the device exceeds the
programmed setpoint temperature, this transistor is activated
causing its collector to become a low impedance. A pull-up
resistor, such as the internal 200 kΩ provided, is needed to
observe a change in the output voltage. For versatility, the
optional pull-up resistor has not been permanently connected
to the output pin. Instead, this resistor is undedicated and
connects from Pin 7 (VS) to Pin 1 (R PULL-UP). In order to use
RPULL-UP a single connection should be made from Pin 1
(RPULL-UP) to Pin 2 (OUT).
The 200 kΩ pull-up resistor can drive CMOS loads since
essentially no static current is required at these inputs. When
driving “LS” and other bipolar family logic inputs a parallel
resistor may be necessary to supply the 20 µA–50 µA IIH (High
Level Input Current) specified for such devices. To determine
the current required, the appropriate manufacturer’s data sheet
should be consulted. When the output is switched, indicating an
over temperature condition, the output is capable of pulling
down with 10 mA at a voltage of about 375 mV. This allows for
a fan out of 2 with standard bipolar logic and 20 with “LS”
family logic.
Table I. Thermal Resistance (SO-8)
uJA (8C/Watt)
t (sec)*
Moving Air**
Without Heat Sink
100
3.5
Still Air
Without Heat Sink
190
15
NOTES
**The time constant is defined as the time to reach 63.2% of the final temperature change.
**1200 CFM.
Low power indicator LEDs (up to 10 mA) can be driven
directly from the output pin of the AD22105. In most cases a
small series resistor (usually of several hundred ohms) will be
required to limit the current to the LED and the output
transistor of the AD22105.
USING THE AD22105 AS A COOLING SETPOINT
DETECTOR
The AD22105 can be used to detect transitions from higher
temperatures to lower temperatures by programming the
setpoint temperature 4°C greater than the desired trip point
temperature. The 4°C is necessary to compensate for the
nominal hysteresis value designed into the device. A more
precise value of the hysteresis can be obtained from Figure 6. In
this mode, the logic state of the output will indicate a HIGH for
under temperature conditions. The total device error will be
slightly greater than the specification value due to uncertainty in
hysteresis.
MOUNTING CONSIDERATIONS
If the AD22105 is thermally attached and properly protected, it
can be used in any measuring situation where the maximum
range of temperatures encountered is between –40°C and
+150°C. Because plastic IC packaging technology is employed,
excessive mechanical stress must be avoided when fastening the
device with a clamp or screw-on heat tab. Thermally conductive
epoxy or glue is recommended for typical mounting conditions.
In wet or corrosive environments, an electrically isolated metal
or ceramic well should be used to protect the AD22105.
APPLICATION HINTS
EMI Suppression
THERMAL ENVIRONMENT EFFECTS
Noisy environments may couple electromagnetic energy into the
RSET node causing the AD22105 to falsely trip or untrip. Noise
sources, which typically come from fast rising edges, can be
coupled into the device capacitively. Furthermore, if the output
signal is brought close the RSET pin, energy can couple from the
OUT pin to the RSET pin potentially causing oscillation. Stray
capacitance can come from several places such as, IC sockets,
multiconductor cables, and printed circuit board traces. In some
cases, it can be corrected by constructing a Faraday shield
around the RSET pin, for example, by using a shielded cable with
the shield grounded. However, for best performance, cables
should be avoided and the AD22105 should be soldered directly
to a printed circuit board whenever possible. Figure 13 shows a
sample printed circuit board layout with low inter-pin capacitance and Faraday shielding. If stray capacitance is unavoidable,
and interference or oscillation occurs, a low impedance capacitor should be connected from the RSET pin to the GND pin.
This capacitor must be considerably larger than the estimated
stray capacitance. Typically several hundred picofarads will correct the problem.
The thermal environment in which the AD22105 is used
determines two performance traits: the effect of self-heating on
accuracy and the response time of the sensor to rapid changes in
temperature. In the first case, a rise in the IC junction temperature above the ambient temperature is a function of two variables:
the power consumption of the AD22105 and the thermal
resistance between the chip and the ambient environment, θJA.
Self-heating error can be derived by multiplying the power
dissipation by θJA. Because errors of this type can vary widely for
surroundings with different heat sinking capacities, it is
necessary to specify θJA under several conditions. Table I shows
how the magnitude of self-heating error varies relative to the
environment. A typical part will dissipate about 230 µW at
room temperature with a 3.3 V supply and negligible output
loading. In still air, without a “heat sink,” Table I indicates a
θJA of 190°C/W, which yields a temperature rise of 0.04°C.
Thermal rise of the die will be considerably less in an environment of turbulent or constant moving air or if the device is in
direct physical contact with a solid (or liquid) body.
REV. 0
Medium
–7–
AD22105
Leakage at the RSET Pin
OUTLINE DIMENSIONS
Leakage currents at the RSET pin, such as those generated from a
moist environment or printed circuit board contamination, can
have an adverse effect on the programmed setpoint temperature
of the AD22105. Depending on its source, leakage current can
flow into or out of the RSET pin. Consequently, the actual
setpoint temperature could be higher or lower than the intended
setpoint temperature by about 1°C for each 75 nA of leakage.
With a 5 V power supply, an isolation resistance of 100 MΩ
would create 50 nA of leakage current giving a setpoint
temperature error of about 0.7°C (the RSET pin is near ground
potential). A guard ring can be placed around the RSET node to
protect against leakage from the power supply pin (as shown in
Figure 13).
Dimensions shown in inches and (mm).
0.1968 (5.00)
0.1890 (4.80)
0.1574 (4.00)
0.1497 (3.80)
PIN 1
0.0098 (0.25)
0.0040 (0.10)
VS
C1
C2099–6–1/96
8-Lead SOIC
(SO-8)
SEATING
PLANE
RSET
8
5
1
4
0.2440 (6.20)
0.2284 (5.80)
0.0688 (1.75)
0.0532 (1.35)
0.0500 0.0192 (0.49)
(1.27) 0.0138 (0.35)
BSC
0.0196 (0.50)
x 45°
0.0099 (0.25)
0.0098 (0.25)
0.0075 (0.19)
8°
0°
0.0500 (1.27)
0.0160 (0.41)
GND
PIN 1
OUT
PRINTED IN U.S.A.
Figure 13. Suggested PCB Layout
–8–
REV. 0