PerkinElmer A2TPMI334AOCA Thermopile with integrated signal processing circuit Datasheet

Datasheet
A2TPMI Ô
Thermopile with integrated signal processing circuit
FEATURES
APPLICATIONS
·
·
·
·
·
·
·
·
·
·
·
·
Smart thermopile sensor with integrated
signal processing.
Can be adapted to your specific measurement task.
Integrated, calibrated ambient temperature sensor.
Output signal ambient temperature compensated.
Fast reaction time.
Different optics and IR filters available.
Digital serial interface for calibration and
adjustment purposes.
Analog frontend/backend, digital signal
processing.
2
E PROM for configuration and data storage.
Configurable comparator with high/low
signal for remote temperature threshold
control.
TO 39 6 pin housing.
·
·
·
·
·
Miniature remote non contact temperature
measurement (pyrometer).
Temperature dependent switch for alarm or
thermostatic applications
Residential, commercial, automotive, and industrial climate control.
Household appliances featuring a remote temperature control like microwave oven, toaster,
hair dryer.
Temperature control in laser printers and copiers.
Automotive climate control.
FUNCTIONAL DIAGRAM
Offset correction
Switch C
+
V1
TP
+
V2
VTobj
Switch A
PTAT
Signalprocessor
Vref
Comp 1
Comp 2
Serial Interface
(SCLK, SDAT)
Switch B
TP:
PTAT:
Thermopile
Temperature Sensor
A2TPMI Datasheet Rev4
VTamb / VRef
Control Unit
VTobj :
VTamb :
VRef :
Page 1 of 21
Switch D
Output voltage object temperature
Output voltage ambient temperature
1.225 V reference voltage
Rev. Oct 2003
Datasheet
A2TPMI Ô
DESCRIPTION
The PerkinElmer A2TPMI is a versatile infrared thermopile sensor with an integrated configurable ASIC
for signal processing and ambient temperature compensation. This integrated infrared module senses
the thermal radiation emitted by objects and converts this to a analog voltage.
The A2TPMI can be delivered fully factory calibrated and adapted to the customer specification, as well
as customer programmable via the serial interface. In the pre-calibrated version, only three pins are
necessary for operation: object output voltage, 5V supply voltage, and ground.
As described in this specification, the temperature accuracy of the fully adjustable integrated circuit outperforms that of the previous PerkinElmer thermopile modules with discrete components on pcb, because the A2TPMI features an offset correction of the amplifier and a factory calibrated ambient temperature sensor. This makes the A2TPMI a versatile, compact and high precision device.
Due to the internal digital signal processing and 8 bit resolution of the internal control registers the
2
A2TPMI has improved accuracy for adjustment and improved performance. E PROM technology allows
unlimited changing of the configuration.
For amplification of the highly sensitive thermopile signal in the micro- to millivolt range, a high resolution programmable low noise chopper amplifier is provided. An adjustable high precision ambient temperature sensor followed by a signal processor, offers an accurate compensation signal with polynomial
characteristics that perfectly matches to that of the thermopiles output. Adding of these signals results in
an ambient independent object temperature signal over a large temperature range, which still can be
adapted / scaled to customer needs due to flexible offset and postgain adjustment facilities of the device.
The two configurable comparators of the A2TPMI, that can alternatively be used, enhance the functionality. This allows to employ the A2TPMI as an temperature dependent switch for alarm purposes.
Threshold temperatures and the hysteresis is free programmable for both comparators.
Due to integration of sensor and electronic in a compact TO 39 housing, the A2TPMI is robust and
insensitive to environmental influences like pcb contamination (leakage currents), humidity and electromagnetic interference.
A2TPMI Datasheet Rev4
Page 2 of 21
Rev. Oct 2003
A2TPMI Ô
Datasheet
TPMI Ordering Information
Part code:
Series (sn)
A2
sn
TPMI
n3c
xxx
Gxx
Oxx
nnn
Pnx
MxGxx
xxxx
analog ASIC - version 1
TPMI
- TO 39 housing
- 5 isolated pins, 1 ground pin to housing
- internal ASIC for signal conditioning
Sensor chip and cap (n3c)
chip:
2
0.7 x 0.7 mm absorber (standard)
n=3
digit "3":
cap:
c=4
c=6
c=7
temperature reference included (standard for TPMI)
2
standard cap, window diameter 2.5 mm , fov = 60°
/ lens cap of various lengths
high cap, additional internal optics, e.g. internal reflector (IR)
2
square hole 3.5 x 3.5 mm , low cap, large fov = 100°
Sensor optics (xxx)
blank
standard filter with 5.5 µm cut-on wavelength
L-x.y
silicon lens with x.y mm focal length
IRA
internal reflector (mirror)
A
internal aperture
Infrared filter on sensor (Gxx)
blank
standard filter with 5.5 µm cut-on wavelength
G9
pyrometry filter, 8..14 µm bandpass
Gxx
PerkinElmer specified broadband or (narrow) bandpass filter
Output configuration (Oxx)
Pin VTobj
A
ambient temperature compensated output voltage representing object temperature
B
not compensated output voltage
C
comparator 1 enabled
Pin VTamb
A
V
C
output voltage representing ambient (sensor) temperature
Vref = 1.225 V
comparator 2 enabled
Temperature sensing range (n)
nnn
-20 ... nnn°C (remark: for object T range < 100°C the min. T-range may be >20°C)
Option: Printed circuit board (pcb)
standard pcb 17 x 33 mm2
P1
mini pcb 17 x 20 mm2
P3
L1 or L2
electrical low pass filter on pcb (L1 = 1st order with RC; L2 = 2nd order with OpAmp)
Option: External optics and filter
ML / MR / MF mirror left / right / front looking
G
standard filter glued to mirror
G12
G12 (uncoated silicon) filter glued to mirror
Option: Connector
blank
none
WTB
wire to board
I / JxT
I = customer specific connector / J = standard JST connector, x = no of pins, top entry
I / JxS
I = customer specific connector / J = standard JST connector, x = no of pins, side entry
I / JxxC
with counterpart
A2TPMI Datasheet Rev4
Page 3 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
Examples:
·
A2TPMI 334-L5.5 OAA 100 and A2TPMI 334-L5.5 OAA 300
are standard configurations of the PerkinElmer TPS 334 sensor with integrated A2TPMI ASIC and
lens optics with 7° field of view adapted to an object temperature range –20…+100°C and
-20…300°C, respectively.
·
A2TPMI 334 OAA 140 P1L1 MLG12 J4T
features the PerkinElmer TPS 334 sensor with integrated A2TPMI ASIC on a standard pcb (P1).
An RC circuit serves as a low pass filter to block the chopper frequency. The optics is the standard
left looking mirror with attached protection filter. A 4 pin JST connector with top entry is used. The
object temperature range is set to –20…100°C. Typical module for microwave oven application.)
·
A2TPMI 334 OAA 60
features the PerkinElmer TPS 334 sensor with integrated A2TPMI ASIC. No additional optics – the
sensor looks with full field of view into the surrounding. The temperature range is –10…60°C. (This
is a typical module for air conditioner application.)
·
A2TPMI 334 L5.5 OAA 250 P3L2 J6S
features the PerkinElmer TPS 334-L5.5 sensor with integrated A2TPMI ASIC and build-in 5.5 mm
nd
lens on a miniature pcb. It has an additional 2 order low pass filter with operation amplifier to
block the chopper frequency. The connector is a 6 pin side entry connector and the temperature
range is –20…250°C. This is a high performance module for industrial applications. The 6 pin connector gives access to the serial interface of the module.
·
For data visualization and for configuration changes a versatile application kit with PC software is
available. Please ask for details.
Labeling
Sensor:
SSSS
XYY
HHH
AA
Last four digits of the device part number
X = Last digit of the calendar year, YY = Week of the calendar year
Serial number of the production lot
Calibration encoding
Example:
SSSS
XYYHHH
AA
A
A
XYYHHH
PCB Version:
Sensors assembled on a PCB are labeled with a sticker having a letter and a serial number printed on.
The letter describes the manufacturing site as follows:
H
B
E
Production parts made in Germany
Production parts made in Indonesia
Engineering samples
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
Absolute Maximum ratings
Parameter
Min
MAX
Supply Voltage VDD
-0.3 V
+6.5 V
Storage Temperature Range (Note 1)
-40 °C
100°C
Operating Temperature Range
-25°C
100°C
Voltage at all inputs and outputs (Note 1)
-0.3 V
VDD +0.3 V
Current at input pins (Note 2)
+/- 5mA
Lead temperature (Soldering, 10sec)
+300°C
ESD Tolerance (Note 3)
2.5 kV
Note 1: Extension to 120°C for limited periods of several minutes possible
Note 2: Limiting input pin current is only necessary for input voltages that exceed absolute maximum input voltage ratings
Note 3: Human body model, 1.5kW in series with 100pF. All pins rated per method 3015.7 of MIL-STD-883.
Static-sensitive device. Unused devices must be stored in conductive material. Protect devices from static discharge and static
fields. Stresses above those listed under “Absolute maximum ratings” may cause permanent damage to the device. Exposure to
absolute maximum rating conditions for extended periods may affect device reliability.
Precautions should be taken to avoid reverse polarity of power supply. Reversed polarity of power supply results in a destroyed
unit.
Do not expose the sensors to aggressive detergents such as freon, trichlorethylen, etc. Optical windows (e.g. filter, lens) may be
cleaned with alcohol and cotton swab.
Electrical Characteristics
Unless otherwise indicated, all limits specified for TA = 25°C, VDD = +5 V
Symbol Parameter
Min
Typ
Max
Unit
4.5
5
5.5
V
1.5
2
mA
VDD –
0.25V
V
100
W
Conditions
Power Supply
VDD
Supply Voltage
IDD
Supply Current
RL > 1MW
Outputs VTobj / VTambESD
VO
Output Voltage Swing
RO
Output Resistance
RL
Resistive Output Load
CL
Capacitive Output Load
ISC
Output short circuit current
0.25
50
Iout: -100mA … +100mA
kW
100
500
pF
6
mA
Sourcing
13
mA
Sinking
Serial Interface SDAT, SCLK
ViL
Low level input voltage
ViH
High level input voltage
IiL
Low level input current
IiH
High level input current
A2TPMI Datasheet Rev4
0.3 VDD
0.7VDD
-600
Page 5 of 21
V
V
-200
mA
1
mA
Rev. Oct 2003
A2TPMI Ô
Datasheet
Electrical Characteristics (continued)
Symbol Parameter
VoL
VoH
Min
Typ
Low level output voltage
High level output voltage
Max
Unit
0.5
V
Output current £ 2mA
V
output current ³ -2mA
V
RL > 1MW, TA = 25°C
VDD0.6V
Conditions
Reference Voltage
VRef
TCVRef
Reference voltage
1.223
Temperature coefficient of reference voltage
1.225
1.227
±30
±100
ppm K
-1
AC Characteristics
Unless otherwise indicated, all limits specified for TA = 25°C, VDD = +5V
Symbol Parameter
Min
Typ
Max
Unit
InN
V1 Input referred voltage noise
120
nV/ÖHz
tStrt
Response Time after Power On
1
s
tlat
Latency time for VTobj
75
ms
tresp
Response Time
90
150
ms
Typ
Max
Unit
Conditions
rms value
Thermopile Characteristics
Symbol Parameter
Min
Conditions
3-type chip (TPS 33x)
S
Sensitive (absorber) area
N
t
2
0.7x0.7
mm
Noise voltage
38
nV/ÖHz
Time constant
25
ms
VTobj / VTamb Characteristics
The VTobj and the VTamb characteristics of thermopile sensors depends not only on object and ambient
temperature but on several other factors like object size to spot size relation, ambient temperature compensation behaviour or optical filter characteristics. Therefore it is not possible to specify a general VTobj
and VTamb characteristic. Those characteristics will be specified application specific in a separate customer specification.
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
Optical Characteristics
Radiation Source
Relative output signal
Aperture
The A2TPMI is available with different
standard optical cap assemblies with
and without an infrared lens or mirror.
FOV at half
energy points
The optics defines the view angle or
field of view (FOV) of the sensor.
Distance 2m
100%
The FOV is defined as the incidence
angle difference, where the sensor
shows 50% relative output signal according to the setup shown.
50%
TPMI
Angle of incidence
Figure 1:
FOV definition
Rotation
Symbol Parameter
Min
Typ
Max
Unit Conditions
Standard Cap Type (C4)
FOV
Field of view
60
70
°
OA
Optical axis
0
± 10
°
50% rel. output signal
High cap type with internal reflector (C6 IRA)
FOV
Field of view
15
20
°
50% rel. output signal
OA
Optical axis
0
±2
°
100
105
°
50% rel. output signal
125
135
°
10% rel. output signal
0
±10
°
7
12
°
50% rel. output signal
50% rel. output signal
Low cap type (C7)
FOV
OA
Field of view
Optical axis
Mirror Module (ML / MR / MF)
Field of view
Lens Cap Type (L5.5)
FOV
Field of view
7
12
°
OA
Optical axis
0
± 3.5
°
D:S
Distance to spot size ratio
A2TPMI Datasheet Rev4
8:1
Page 7 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
Optical Characteristics (continued)
Symbol Parameter
Min
Typ
Max
Unit Conditions
Lens Cap Type (L10.6)
FOV
Field of view
5
8
°
OA
Optical axis
0
±2
°
D:S
Distance to spot size ratio
50% rel. output signal
11:1
Filter Characteristics
Parameter
Min
Typ
Max
Unit Conditions
Standard Filter
Average Transmission
70
%
Average Transmission
Cut On
5.2
5.5
0.5
%
5.8
µm
Wavelength range from
7.5 µm to 13.5 µm
Wavelength range from
visual to 5 µm
At 25°C
G9 Filter
Average Transmission
70
%
Average Transmission
Cut On
7.8
8
1
%
8.2
µm
Wavelength range from 9
µm to 13 µm
Wavelength range from
visual to bandpass
At 25°C
Uncoated Silicon Lens (G12)
Average Transmission
52
%
Wavelength range from
5.5 µm to 13.5 µm
PerkinElmer offers a wide range of Infrared Filters available in many different filter characteristics.
Please contact PerkinElmer if you have special requirements or need further information.
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
General Description
THERMOPILE SENSOR
The signal voltage, generated by the infrared radiation-sensitive thermopile sensor, is preamplified by a
programmable choppered amplifier with 8 bit resolution.
Due to the principle of thermopile temperature measurements, the thermopile voltage can be positive or
negative depending if the object temperature is higher or lower than the ambient temperature of the
A2TPMI. In order to allow signal processing of negative voltages with a single supply system, all internal
signals are related to an internal voltage reference (Vref) of nominal 1.225 V, which serves as a virtual
analog ground.
For offset voltage trimming of the thermopile amplification path, the preamplifier is followed by a
programmable trimming stage generating an offset voltage with a resolution of 8 bit.
The thermopile voltage shows a non-linear output characteristic versus the object temperature.
AMBIENT TEMPERATURE SENSOR
The temperature of the A2TPMI, respectively the thermopile sensor, is detected by an integrated temperature sensor. This signal will be amplified and signal processed in order to match the reverse characteristics of the amplified thermopile curve, to realize an optimum of ambient temperature compensation after adding the two signals. The characteristics of the temperature sensor signal is adjustable.
This adjustment is part of the ASIC production process and will be provided by PerkinElmer. Thus the
characteristics of the A2TPMI ambient temperature signal VTamb is always provided fully calibrated.
AMBIENT TEMPERATURE COMPENSATION
The thermopile sensor converts the temperature radiation of an object surface to an electrical signal by
means of thermocouples (Seebeck effect). The sensor output voltage is caused by the temperature
difference between radiation heated (hot) junctions and cold junctions with a good thermal contact to the
housing.
In order to deliver an output signal which is only dependent on the object temperature, any change of
housing (ambient) temperature has to lead to an appropriate output signal correction.
For temperature compensation, the amplified thermopile- and temperature reference signals (VTambint)
are added in an adding amplifier stage. The amplification is adjustable in a wide range according to
application / customer requirements.
The ambient temperature compensated and amplified signal is supplied to the output VTobj. The temperature reference signal or alternatively the bandgap reference voltage is available on a second output
pin VTamb. Both outputs are short circuit stable .
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
CONTROL UNIT / SERIAL INTERFACE
The operation characteristics of the A2TPMI have to be configured with a set of internal random access
registers. All parameters / configurations are permanently stored in E2PROM in parallel, Configuration
is usually done during factory calibration and does not need any user input.
The control unit offers via serial interface access to all the registers, i.e. the internal parameters of the
A2TPMI. The serial interface is a two wire bi-directional synchronous (SDAT, SCLK) type. A2TPMI sensors are in general factory calibrated and therefore there is no need to use the serial interface for standard applications.
The SDAT- / SCLK pins are internally pulled up to VDD and can be left unconnected. If the SDAT /
SCLK pins will be connected in the application, ensure signal conformity to the serial interface specification. Subsequent undefined signals applied to these pins, may change the configuration and lead to
malfunctioning of the sensor.
For detailed information about the serial interface refer to application note: A2TPMI Serial Interface description, or contact PerkinElmer application support.
OUTPUT CONFIGURATION
The A2TPMI offers various output configurations, which can be configured via the serial communication
interface by means of integrated analog switches. For each output it can be individually selected
whether the output operates in ‘Analog mode’ or in ‘Comparator mode’.
In ‘Analog mode’ the output signal represents the measured IR radiation, respectively the temperature
as an analog DC voltage.
In ‘Comparator mode’ the measured IR radiation, respectively the temperature is compared to a programmed threshold. For slowly changing signals an additional hysteresis can be configured. If the
measured signal is above the threshold, +5VDC (logical high) is applied to the output. If the measured
signal is below the threshold, 0VDC (logical low)is applied to the output.
For detailed information about the output configuration refer to application note: A2TPMI Serial Interface
description, or contact PerkinElmer application support.
A2TPMI Datasheet Rev4
Page 10 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
Application Information
AMBIENT TEMPERATURE COMPENSATION
Because of many physical effects, that influence the non-contact temperature measurement based on
infrared radiation, it is difficult to meet the best initial adjustment for a specific application. Therefore
some deviations might be found at first measuring. For all applications the optimized solution can be
prepared and fixed based on the measurement in the application environment. PerkinElmer is pleased
in providing you assistance to find the conditions, which deliver the highest accuracy in your application.
The temperature compensation is only working well within a certain ambient temperature range, limited
by different device parameters of the thermopile sensor and the temperature reference sensor. The
following diagram shows a typical characteristics and is only an example for better understanding of the
principle compensation curve. The curve shows the deviation for a correct working of a compensated
module.
Temperature Deviation of VTobj vs. Ambient Temperature
Typical Temperature Deviation [K]
3
2,5
2
1,5
1
0,5
0
-20
0
20
40
60
80
100
-0,5
Ambient Temperature [°C]
The compensation of the module sample in the diagram is adjusted to the best fitting at 20°C to 80°C
ambient temperature, but the curve can be shifted in the whole ambient temperature range through the
change of A2TPMI parameters.
MEASUREMENT TOLERANCE
The temperature error of the A2TPMI depends on several factors like the emissivity, object temperature,
object size to spot size relation, temperature gradients over the sensor housing in the environment,
device tolerances and the optimal adjustment of the ambient temperature compensation.
The accuracy as specified under VTamb and VTobj characteristics is based on theoretical calculation as
well as on statistical evaluation results. The PerkinElmer quality system ensures that all A2TPMIs are
calibrated and tested under a certain test conditions in order to guarantee these specifications.
However, due to the nature of infrared remote temperature measurements there might occur limits exceeding or deviations in specific application environments. In this case please contact the PerkinElmer
application support to help you solving the problem.
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
OUTPUT SIGNAL
The A2TPMI amplifiers are realized in chopper amplifier technology. Due to the nature of this technology the output signals VTobj and VTamb incorporate an AC signal of approximately 10 mV peak to peak in
the range of 250 kHz. This AC voltage can be suppressed either by an electrical low pass filter or via an
additional software filtering.
In applications with low resistive load ( > 1Mohm) a simple RC low pass filter as follows can be used to
smooth the signal:
500 Ohms
A2TPMI
VTobj or VTamb
VTobj or VTamb filtered
L1 Option
³470 nF
In applications with high resistive load (50kOhm … 1MOhm) filtering can be achieved with the following
circuit. A rail to rail OPAmp like the LMV358 should be used so that the full sensing range will be available on the output of the filter circuit.
C
L2 Option
R
R
A2TPMI
VTobj or VTamb
LMV358
+
C
-
VTobj or VTamb filtered
R = 10kOhms
C = 100nF
PRINTED CIRCUIT BOARD (PCB) VERSION
2
Two different sizes of standard PCB versions are available. P1 version is a 17 x 34 mm PCB which
2
allows assembly of additional external mirror optics (M options). P3 version is 17 x 20 mm PCB suitable for applications with restricted space. P3 version is not available with mirror (M option).
st
Each PCB version is available either as plain version (sensor directly wired to connector), or with 1
nd
order (RC-circuit, L1 option) or 2 order (active OpAmp circuit, L2 option) low pass filter, in order to
provide attenuation of the AC portion on the output signal as described in chapter Output Signal.
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
The PCB versions are available with following connector assemblies:
Connection type
Manufacturer: Model No.
Header
Connector
JST: B 4B-PH-K-S
Housing: PHR 4
Contact: SPH-004T-P0.5S
JST: S 4B-PH-K-S
JST: B 6B-PH-K-S
Housing: PHR 6
Contact: SPH-004T-P0.5S
JST: S 6B-PH-K-S
4 pin top entry
4 pin side entry
6 pin top entry
6 pin side entry
Contact Material: Phosphor bronze ; tin-plated,
2
Applicable wire: 0.032 to 0.08mm
Insulation O.D.: 0.5 to 0.9 mm
Note: Engineering samples will be delivered only with a 6 pin header and counterpart connector with
350 mm cable.
OUTPUT LOAD
Capacitive loads which are applied directly to the outputs reduce the loop stability margin. Values of
100 pF can be accommodated. Resistive load for the outputs should be held as small as possible (i.e. a
large load resistance, Rload > 50 kW has to be used) in order to avoid an impact on the temperature signal due to self heating of the module.
RESPONSE TIME
The response time to an object temperature jump depends on the time constant t of the thermopile and
the signal processing time of the A2TPMI. The processing of the thermopile signal has a latency time
(tlat) of max. 75ms caused by the time required for AD-conversion, DA conversion and signal processing. The following diagram explains the connection of these events
Tobj 2
Tobj 1
t
t
lat
t
resp
t
t
lat
resp
t
VTobj 2
63%
37%
VTobj 1
Figure 2:
response time definition
The A2TPMI has a sampling rate of 30 samples / second which results in a resolution of approx. 30ms
for dynamic signals at VTobj.
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
LATCHUP AVOIDANCE
Junction isolated CMOS circuits inherently include a parasitic 4 layer (PNPN) structure which has characteristics similar to a thyristor (SCR). Under certain circumstances this junction may be triggered into a
low impedance state, resulting in excessive supply current, which can thermally destroy the circuit.
To avoid this condition, no voltage greater than 0.3 V beyond the supply rails should be applied to any
pin. In general the ATPMI supplies must be established either at the same time or before any signals
are applied to the inputs. If this is not possible the drive circuits must limit the input current flow to
maximum 5mA to avoid latchup. In general the device has to be operated with a 100 nF capacitor in
parallel to the power supply.
SOLDERING
The TPMI is a lead-free component and fully complies with the ROHS regulations, especially with existing roadmaps of lead-free soldering. The terminations of the TPMI sensor consist of nickel plated Kovar
and gold finish. Hand soldering is recommended.
A2TPMI Datasheet Rev4
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Rev. Oct 2003
Datasheet
A2TPMI Ô
Packaging Information
TO39 with Standard cap (C4):
TO 39 with 5.5mm focal length Si lens
(L5.5):
A2TPMI 334
A2TPMI 334-L5.5
6±1
0.5
6±1
9.3 max
9.3 max
8.2 max
Æ 5.5
8.2 max
sensor surface
Æ 6.5 max
Æ 2.5
Æ0.41 – 0.48
Æ 0.41 – 0.48
0.81 ± 0.15
1.9 ± 0.1
0.81 ± 0.15
4.2 ± 0.2
8.25 ± 0.2
22.5°
22.5°
45°
0.89 ± 0.15
45°
0.89 ± 0.15
Æ 5.84
Æ 5.84
TO39 with high cap and int. reflector
TO39 with low cap and square hole (C7)
(C6 IRA):
A2TPMI 337
A2TPMI 336 IRA
6±1
0.7 ± 0.2
6±1
9.3 max
0.7 ± 0.2
9.3 max
sensor surface
8.25 max
Æ 5.0 – 5.6
sensor surface
8.25 max
3.2 – 3.6
Æ0.41 – 0.48
1.9 ± 0.1
Æ1.4 max
Æ0.41 – 0.48
0.3 max
1.15 ± 0.2
0.81 ± 0.15
0.81 ± 0.15
13.35 – 13.75
3.05 – 3.4
22.5°
22.5°
45°
0.89 ± 0.15
Æ 5.84
Æ 5.84
A2TPMI Datasheet Rev4
45°
0.89 ± 0.15
Page 15 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
Packaging Information (continued)
TO 39 with 10.6mm focal length Si lens
(L10.6):
A2TPMI 334-L10.6
6 ± 0.5
9.3 max
8.2 max
sensor surface
Æ 5.5
Æ0.41 – 0.48
max
0.81 ± 0.1
1.9 ± 0.1
13.9 ± 0.1
22.5°
45°
0.89 ± 0.1
Æ 5.84
A2TPMI Datasheet Rev4
Page 16 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
PCB Version P1 J4S
8.25 max
A
4.8
1.1
4 max
37.4 ± 0.3
Dimensions
(Cap Type)
C4
C6IRA
C7
L5.5
L10.6
A
4.3 ± 0.3
13.6 ± 0.3
3.5 ± 0.3
8.3 ± 0.3
14.0 ± 0.3
J6S
33 ± 0.3
1.5
1.5
Dimensions B
Refer to sensor drawings
17± 0.3
13.7
9.9
Æ2
B
13.9
1.65 ± 0.4
7.7
11.1
6 ± 0.4
PCB Version P1 J4T
8.25 max
6.2 max
A
4 max
1.1
J6S
±
4.5
13.7
9.9
Æ2
B
4.3 ± 0.3
13.6 ± 0.3
3.5 ± 0.3
8.3 ± 0.3
14.0 ± 0.3
1.5
1.5
17± 0.3
A
Dimensions B
Refer to sensor drawings
33 0.3
4.5
Dimensions
(Cap Type)
C4
C6IRA
C7
L5.5
L10.6
13.9
1.65 ± 0.4
7.7
A2TPMI Datasheet Rev4
11.1
6 ± 0.4
Page 17 of 21
Rev. Oct 2003
Datasheet
MR Type
PCB Version P1 J4S with external Mirror
13.5 max
A2TPMI Ô
view
direction
13.5 max
view
direction
15 max
9 ± 0.5
4.8
1.1
ML Type
4 max
37.4 ± 0.3
view
direction
J6S
33 ± 0.3
1.5
17± 0.3
9.9
Æ2
13.7
1.5
13.9
MF Type
11.1
6 ± 0.4
1.65 ± 0.4
view
direction
PCB Version P1 J4T with external Mirror
13.5 max
13.5 max
view
direction
6.2 max
15 max
9 ± 0.5
4 max
1.1
J6S
33 ± 0.3
4.5
4.5
1.5
1.5
17± 0.3
13.7
9.9
Æ2
13.9
1.65 ± 0.4
11.1
A2TPMI Datasheet Rev4
6 ± 0.4
Page 18 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
PCB Version P3 J4S
8.25 max
1.1 ± 0.2
A
4.8
8.2
24.25 max
9.9
20 ± 0.2
18.2 ± 0.2
7.3 ± 0.1
J6S
15.2 ± 0.2
A
4.3 ± 0.3
13.6 ± 0.3
3.5 ± 0.3
8.3 ± 0.3
14.0 ± 0.3
Dimensions B
Refer to sensor drawings
Æ2.3
17 ± 0.2
Dimensions
(Cap Type)
C4
C6IRA
C7
L5.5
L10.6
B
Æ1
6.5 ± 0.1
13 ± 0.1
13.9
PCB Version P3 J4T
8.25 max
1.1 ± 0.2
A
9.4
6.0
4.5
20.8 max
9.9
20 ± 0.2
18.2 ± 0.2
7.3 ± 0.1
15.2 ± 0.2
A
4.3 ± 0.3
13.6 ± 0.3
3.5 ± 0.3
8.3 ± 0.3
14.0 ± 0.3
Dimensions B
Refer to sensor drawings
Æ 4.2 ± 0.2
Æ2.3
17 ± 0.2
J6T
Dimensions
(Cap Type)
C4
C6IRA
C7
L5.5
L10.6
B
9.4
6.0
Æ1
6.5 ± 0.1
13 ± 0.1
A2TPMI Datasheet Rev4
13.9
Page 19 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
Connection Information
PCB Version P1 J4S
PCB Version P1 J4T
VTobj
GND
VDD
VTamb
PCB Version P1 J6S
VTobj
GND
VDD
VTamb
PCB Version P1 J6T
VTobj
GND
VDD
VTamb
SCLK
SDAT
PCB Version P3 J4S
VTobj
GND
VDD
VTamb
SCLK
SDAT
PCB Version P3 J4T
VTobj
GND
VDD
VTamb
VTobj
GND
VDD
VTamb
PCB Version P3 J6S
PCB Version P3 J6T
VTobj
GND
VDD
VTamb
SCLK
SDAT
VTobj
GND
VDD
VTamb
SCLK
SDAT
Non PCB Version
VTobj
VDD
GND
VTamb
SDAT
SCLK
Bottom view
A2TPMI Datasheet Rev4
Page 20 of 21
Rev. Oct 2003
Datasheet
A2TPMI Ô
Liability Policy
The contents of this document are subject to change without notice. Customers are advised to consult
with PerkinElmer Optoelectronics sales representatives before ordering.
Customers considering the use of PerkinElmer Optoelectronics thermopile devices in special applications where failure or abnormal operation may directly affect human lives or cause physical injury or
property damage, or where extremely high levels of reliability are demanded, are requested to consult
with PerkinElmer Optoelectronics sales representatives before such use. The company will not be responsible for damage arising from such use without prior approval.
As any semiconductor device, thermopile sensors or modules have inherently a certain rate of failure. It
is therefore necessary to protect against injury, damage or loss from such failures by incorporating safety
design measures into the equipment.
PerkinElmer Optoelectronics GmbH & Co. KG
PO Box 3007
65020 Wiesbaden · Germany
Tel.: +49 (0)611 492 430
Fax: +49 (0)611 492 177
http://www.perkinelmer.com
A2TPMI Datasheet Rev4
Page 21 of 21
Rev. Oct 2003
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