The ASDX Series is a Silicon Pressure Sensor offering a
ratiometric analog output for reading pressure over the
specified full scale pressure span and temperature range.
The ASDX is fully calibrated and temperature compensated for
sensor offset, sensitivity, temperature effects and non-linearity
using an on-board Application Specific Integrated Circuit
(ASIC). Calibrated output values for pressure are updated at
approximately 1 kHz.
The standard ASDX is calibrated over the temperature range
of 0 °C to 85 °C [32 °F to 185 °F]. The sensor is characterized
for operation from a single power supply of either 3.3 Vdc or
5.0 Vdc.
FEATURES
•
•
Ratiometric 12-bit analog output
Precision ASIC conditioning and temperature
compensated over 0 °C to 85 °C [32 °F to 185 °F]
temperature range
•
•
•
•
•
•
Low operating voltage
Absolute, differential and gage types
Pressure ranges from 10 inches H
2
0 to 100 psi
Standard calibrations in inches H
2
0, cm H
2
0, psi, mbar,
bar, kPa
Total error band of ±2.0% of full scale span maximum
RoHS compliant
•
•
•
•
•
•
•
These sensors are available to measure absolute, differential
and gage pressures. The absolute versions have an internal
vacuum reference and an output value proportional to absolute
pressure. Differential versions allow application of pressure to
either side of the sensing diaphragm. Gage versions are
referenced to atmospheric pressure and provide an output
proportional to pressure variations from atmosphere.
The ASDX Series sensors are intended for use with non-
corrosive, non-ionic working fluids such as air and dry gases.
They are designed and manufactured according to standards
in ISO 9001.
POTENTIAL APPLICATIONS
Flow calibrators
Ventilation and air flow monitors
Gas flow instrumentation
Sleep apnea monitoring and therapy equipment
Barometry
Pneumatic controls
HVAC
ASDX Series Silicon Pressure Sensors
Table 1. Absolute Maximum Ratings
Parameter
Supply voltage (V
supply
)
Voltage to any pin
ESD susceptibility (human body model)
Storage temperature
Lead temperature (2 s to 4 s)
2
External capacitance between V
supply
and ground
Table 2. Operating Specifications
Parameter
3
Supply voltage (V
supply
)
3.3 Vdc
5.0 Vdc
Sensors are either 3.3.Vdc or 5.0.Vdc based on models chosen per the
order guide (see Figure 1).
1
Min.
-0.3
-0.3
3
-50 [-58]
-
100
Max.
6.0
V
supply
+ 0.3
-
125 [257]
250 [482]
470
Unit
Vdc
Vdc
kV
°C [°F]
°C [°F]
nF
Min.
3.0
4.75
1.5
0 [32]
-20 [-4]
Typ.
3.3
4
5.0
4
Max.
3.6
5.25
Unit
Vdc
mA
°C [°F]
°C [°F]
Supply current
5
Compensated temperature range
6
Operating temperature range
7
Overpressure
8
Burst pressure
Startup time (power up to data ready)
Response time
Upper output clipping limit
Lower output clipping limit
Minimum load resistance
9
Total error band
Output resolution
Table 3. Environmental Specifications
Parameter
Humidity
Vibration
Shock
Life
Table 4. Wetted Materials
Parameter
Covers
Adhesives
Electronic components
11
-
-
97.5
-
5.0
-
12
2.5
3.5
-
85 [185]
-
105 [221]
2X operating pressure range minimum
3X operating pressure range minimum
-
5
1.0
-
-
-
-
2.5
-
-
-
2.0
-
-
ms
ms
% V
supply
% V
supply
kOhm
10
%FSS
bits
Characteristic
0% to 95% RH non-condensing
10 G at 20 Hz to 2000 Hz
100 G for 11 ms
1 million cycles minimum
Port 1 (Pressure Port)
glass-filled PBT
silicone
silicon and glass
12
Port 2 (Reference Port)
glass-filled PBT
silicone and epoxy
silicon, glass, and gold
12
Notes:
1.
Absolute maximum ratings are the extreme limits that the device will withstand without damage to the device.
2.
An external bypass capacitor is
required
across the supply voltage (Pins 1 and 3 – see Figure 4) as close to the sensor supply pin as possible for correct sensor
operation.
3.
Ratiometricity of the sensor (the ability of the output to scale to the input voltage) is achieved within the specified operating voltage for each option. Other custom
supply voltages are available, please contact Honeywell Customer Service.
4.
The sensor is not reverse polarity protected. Incorrect application of excitation voltage or ground to the wrong pin may cause electrical failure.
5.
The compensated temperature range is the temperature range (or ranges) over which the sensor will produce an output proportional to pressure within the
specified performance limits.
6.
The operating temperature range is the temperature range over which the sensor will produce an output proportional to pressure but may not remain within the
specified performance limits.
7.
Overpressure is the maximum pressure which may safely be applied to the product for it to remain in specification once pressure is returned to the operating
pressure range. Exposure to higher pressures may cause permanent damage to the product.
8.
Burst pressure is the maximum pressure that may be applied to any port of the product without causing escape of pressure media. Product should not be expected
to function after exposure to any pressure beyond the burst pressure.
9.
Total error band is the maximum deviation in output from ideal transfer function over the entire compensated temperature and pressure range. Includes all errors
due to offset, full scale span, pressure non-linearity, pressure hysteresis, repeatability, thermal effect on offset, thermal effect on span and thermal hysteresis.
Specification units are in percent of full scale span (%FSS).
10. Full scale span (FSS) is the algebraic difference between the output signal measured at the maximum (Pmax.) and minimum (Pmin.) limits of the pressure range.
11. Consult Honeywell Customer Service for detailed material information.
12. For the AC pressure port configuration, the “pressure” and “reference” ports are reversed.
2
www.honeywell.com/sensing
Low Pressure and Ultra-Low Pressure Analog Output
Figure 1. Nomenclature and Order Guide
Notes:
13. Other package combinations are possible, please contact Honeywell Customer Service.
14. The transfer function limits define the output of the sensor at a given pressure input. By specifying the output signal at the maximum (Pmax.)
and minimum (Pmin.) limits of the pressure range, the complete transfer curve for the sensor is defined. See Figure 2 for a graphical
representation of each calibration.
15. For a digital output, please refer to the ASDX Digital Series.
:congratulate: :congratulate: :congratulate: I just came into contact with stm32, how do I get started and how do I learn it? Please help! It would be best if there is a video!!!...
I use the STM32F427's FMC to control the SRAM. Since the ports are not enough, I want to use the FMC's data address bus multiplexing function. Do I need to add a latch to latch the address? What is th...
Problem description: Design a controller for a 4-DOF horizontal joint manipulator. Hardware: personal computer, motion control card, hand-cranked pulse generator. Software: VB or VC. Functions: indivi...
As the title says, do you think Stellaris documentation needs to be translated?If you want to translate, what content is generally more valuable to translate?...
SinoWise's SH66xx series 4-bit microcontrollers have the characteristics of fast speed, low power consumption, simple structure, easy to use, and high cost performance. They are widely used in remo...[Details]
TD-SCDMA (Time Division Synchronous Code Division Multiple Access) is one of the three major standards for the third generation of mobile communications. It is a communication standard with indepen...[Details]
Digital signal processors have efficient numerical computing capabilities and can provide a good development environment, while programmable logic devices have highly flexible configurability. This...[Details]
Microelectromechanical systems (MEMS) are gradually entering the consumer, industrial, medical, automotive and computer application markets. Moreover, we cannot ignore their steady progress in the ins...[Details]
Overview
Bioelectric signals are very weak, and there is strong interference when detecting them. Therefore, there are many technical difficulties in designing high-quality bioelectric ampli...[Details]
With the development of automatic control technology, the application of precision air pressure generation and control technology is becoming more and more extensive. However, the traditional valve...[Details]
In the field of software development, the most critical but also the most unpredictable phase is the debugging phase. There are many factors that play a role in the process of software debugging, a...[Details]
Basic principles of simulation
Simulation is a technology used in the field of embedded system development. It can bring system developers the controllability and visibility needed to integra...[Details]
As the whole equipment is becoming increasingly miniaturized and power-saving, low-dropout linear regulators (LDOs) with low power consumption are becoming the mainstream in the market for linear regu...[Details]
In order to ensure the reliability of the driving assistance system and the basic functions of the car, and also to leave suitable connection interfaces for the car's future new entertainment and ...[Details]
With the continuous emergence of new technologies and the increasing complexity of DSP real-time systems, there are more and more different types of external devices. Writing drivers for these exte...[Details]
According to In-Stat/MDR, the number of mobile phones with Bluetooth capabilities will reach at least 300 million by 2005. One of the clear evidences of the increasing adoption of Bluetooth is that...[Details]
Combined with Samsung's ARM9 series embedded processor S3C2410, this paper explains how to perform modular programming of LCD driver and how to statically load the driver into the system kernel.
...[Details]
1 Introduction to suction laminating machine
Suction laminating machine is a kind of woodworking machinery, which can realize the laminating function of wood boards and other materials. It i...[Details]
Preface
In the application of PLL, DLL and CDR circuits, people generally require the output clock signal to have a 50% duty cycle so that data can be sampled at both the rising and fallin...[Details]
Industrial Control Electronics
京公网安备 11010802033920号
EEWORLD
