Absolute Pressure Sensor
CFSensor’s absolute pressure sensor offers greater precision than its relative counterparts and can be used in a wide variety of applications ranging from medical equipment to automotive manufacturing. They’re built to last and made from high-quality materials so they can withstand difficult environments without compromising accuracy and performance.
XGZP6816D Barometric Pressure Sensor
- Wide Ranges: 300hPa ... 1100hPa
- 1.8V~3.6V Power Supply
- Absolute Pressure Type
- Current Consumption:<80uA(single measurement at 128 OSR)
- Standby Current:<100nA (25°C)
- Calibrated Digital Signal (I2C Interface)
- Absolute Pressure Accuracy:±1hPa (8.3m)
- Relative Pressure Accuracy:±0.12hPa (1m)
- Temperature Accuracy:±1°C
XGZP6808D Waterproof Barometric Pressure Sensor (LPS33HW Alternative Parts)
- Pressure range: 300hPa ... 1100hPa (+9000m ... -500m relating to sea level)
- Temperature Range: -40…+85°C
- Supply voltage: 1.7V ... 3.6V (VDD), 1.2V..... 3.6V (VDDIO)
- Relative accuracy: ±0.06hPa, equiv. to ±0.5 m
- Absolute accuracy: typ. ±1hPa (300hPa … 1100hPa)
- Measurement time: Typical: 28 ms. Minimum: 3 ms.
- Average current consumption: High precision: 60 µA, Low power: 3 µA, Standby: <1 µA.
- I2C interface, Embedded 24-bit ADC
- FIFO: Stores latest 32 pressure or temperature measurements.
- Pb-free, halogen-free and RoHS complian
- Water resistance degree: water resistance rating of 100 meters
Waterproof Absolute Pressure Sensor XGZP6826D
- Wide Ranges: 0kPa~100kPa…2500kPa
- Optional 3.3V~5.5V Power Supply
- Absolute Pressure Type
- For Non-corrosive Gas or Air or Liquid
- Calibrated Digital Signal (I2C Interface)(Refer to XGZP6826A for Analog signal)
- Temp. Compensated: 0℃~+60℃ (32℉~+140℉)
- Current Consumption:5uA(single measurement)
- Standby Current:<100nA (25°C)
Ultrasonic Water Level Sensor XGZP6858D
- Wide Ranges: 0kPa~100kPa…700kPa
- Optional 2.5V~5.5V Power Supply
- Absolute Pressure Type
- For Non-corrosive Gas or Air or Liquid
- Calibrated Digital Signal(I2C Interface)(Refer to XGZP6858A for Analog signal)
- Temp. Compensated: 0℃~+60℃(32℉~+140℉)
- Current Consumption :5uA(single measurement)
- Standby Current: <100nA (25°C)
Table of Contents
What Is an Absolute Pressure Sensor?
An absolute pressure sensor is a sensor used to measure pressure relative to absolute zero pressure, which is a perfect vacuum. Unlike gauge pressure sensors that measure pressure relative to atmospheric pressure, it provides a measurement of the total pressure exerted by the fluid or gas being measured, including atmospheric pressure. An absolute pressure sensor typically consists of a sensing element that converts pressure into an electrical signal, and a signal conditioning circuit that amplifies and processes the signal for further use.
What Does an Absolute Pressure Sensor Do?
An absolute pressure sensor is specifically engineered to gauge the overall pressure exerted by a fluid or gas, including the influence of atmospheric pressure that might be present. The sensor ensures a remarkably precise and dependable measurement of the pressure within a system, regardless of the ambient atmospheric pressure. Absolute pressure sensors find widespread utilization in various applications such as altimeters, barometers, and vacuum pumps, where an accurate assessment of pressure relative to a vacuum is indispensable. Moreover, they are employed in industrial environments to effectively monitor systems operating under both low-pressure and high-pressure circumstances.
How Do Absolute Pressure Sensors Work?
The absolute pressure sensor working principle operates through the detection of deflection in a diaphragm or a similar flexible material caused by pressure alterations. A piezoelectric crystal, capacitance diaphragm, or strain gauge can be used as the sensing component. As pressure is exerted, the diaphragm flexes, transmitting the pressure to the sensing element that transforms it into an electrical signal. The sensor’s circuitry processes this electrical signal to deliver an accurate measurement of the absolute pressure.
How Do I Integrate an Absolute Pressure Sensor into My Circuit?
Before you begin, it’s critical to grasp the absolute pressure sensor circuit as well as the specs needed. Typically, absolute pressure sensors output analog signals, which can be easily converted to digital signals for use in microcontrollers. To obtain accurate readings, external factors such as temperature and vibration need to be minimized, Using a signal conditioning circuit can help to amplify and filter the sensor’s output, reducing interference and producing more accurate results.
Here are some steps to Integrating an absolute pressure sensor into your circuit:
- Choose your sensor: The market offers different types of absolute pressure sensors, such as piezoresistive, piezoelectric, capacitive, and strain gauge sensors. You should select a sensor that is suitable for your application and compatible with your circuit.
- Obtain a datasheet: The datasheet provides important information about the sensor, including pinout, specifications, and recommended operating conditions.
- Interface the sensor with your circuit: Absolute pressure sensors typically require power and a signal output connection. Depending on the sensor and circuit requirements, this connection can be via analog voltage or current output, digital output, or serial communication.
- Calibrate and test the sensor: Before integrating the sensor, it is critical to calibrate and test it to guarantee accurate and dependable results. Absolute pressure sensor calibration involves comparing readings taken by the sensor against a known reference, such as a calibrated pressure gauge.
- Integrate the sensor into your circuit: When you have tested and calibrated the sensor, you can integrate it into your circuit by connecting the required power and signal output connections. Follow the manufacturer’s manual and consult the datasheet to ensure correct connection and operation.
Can I Use an Absolute Pressure Sensor in My Design?
In designing a project, selecting the right pressure sensor is crucial to ensure its accuracy and reliability. But choosing the pressure sensor that is suitable for your application may be difficult given the variety of pressure sensors that are currently on the market. One question that may arise is if an absolute pressure sensor can be used in your design. An absolute pressure sensor measures the pressure relative to a perfect vacuum, making it ideal for applications that require accurate information on atmospheric pressure. However, it may not be the best choice for applications that need to measure gauge or differential pressure. It is therefore important to carefully consider the specific requirements of your design before choosing a pressure sensor to ensure maximum efficiency and performance.
Don’t worry, you can contact CFSensor‘s expert to help you get the correct absolute pressure sensors or absolute pressure transmitters quickly.
Absolute Pressure Sensor Applications
Absolute pressure sensors find numerous applications in various fields. Some of the most common applications include:
- Altitude Measurement: Absolute pressure sensors are extensively used in altimeters to measure the altitude of aircraft and other flying objects. By assessing the pressure of the surrounding air in relation to a perfect vacuum, these sensors provide accurate altitude measurements.
- Barometers: Absolute pressure sensors are employed in barometers to gauge atmospheric pressure, enabling weather forecasting and monitoring air pressure fluctuations over time. They are commonly utilized in weather stations and other meteorological applications.
- Vacuum Systems: Absolute pressure sensors play a vital role in vacuum pumps and other vacuum systems by monitoring the pressure to ensure optimal system operation. These sensors help maintain the desired pressure levels.
- Industrial Applications: Absolute pressure sensors are used in various industrial applications to monitor the pressure in systems operating under high or low-pressure conditions. These sensors can be used to ensure that systems are operating within safe pressure limits and to prevent damage or accidents.
- Automotive Applications: Manifold absolute pressure sensors are utilized in automotive engines to measure the pressure in the intake manifold. This information is used to regulate fuel injection and ignition timing, optimizing engine performance. Additionally, these sensors are employed in tire pressure monitoring systems to ensure tires are properly inflated.
Tips for Selecting the Right Absolute Pressure Sensor for Your Project
Selecting the ideal absolute pressure sensor for your project can be a challenging task. However, the following tips can assist you through the selection process:
- Pressure Range: Determine the range of pressures that need to be measured in your application. Ensure that the sensor you choose is capable of accurately measuring within that range.
- Accuracy: Assess the level of precision required for your project. Select a sensor that offers the appropriate level of accuracy to ensure reliable and precise readings.
- Environmental Factors: Consider factors like temperature and humidity that may have an impact on how well the sensor performs. Select a sensor that can perform well in the particular environmental circumstances of your application.
- Output Type: Consider the type of output required by your circuit. Absolute pressure sensors can provide analog voltage or current outputs, digital outputs, or serial communication outputs. Select the output type that is compatible with your circuit’s requirements.
- Cost and Reputation: Evaluate the cost and availability of the sensor, along with the manufacturer’s reputation for quality and reliability. Consider the overall value offered by the sensor in terms of performance, longevity, and support.
FAQs About Absolute Pressure Sensor
What Is the Difference Between Absolute and Relative Pressure Sensors?
The distinction between the absolute sensor and relative sensor lies in the reference point used for pressure measurement. Relative pressure sensors measure the variance between the pressure at the sensing point and the ambient pressure, typically the atmospheric pressure, while an absolute pressure sensor provides a pressure measured relative to a reference of zero pressure, which is as close as possible to a vacuum.
To make it simpler, An absolute pressure sensor monitors the pressure with respect to a vacuum, whereas a relative pressure sensor measures the pressure relative to the surrounding air pressure.
What's the Difference Between Absolute, Gauge and Differential Pressure Sensors?
Absolute, Gauge, and Differential Pressure sensors are types of pressure sensors that differ in the way they measure pressure.
An absolute pressure sensor measures pressure relative to a perfect vacuum or zero pressure. They can be useful in applications that require accurate measurement of low pressures. Absolute pressure sensors are often used when altitude measurements are required, such as in weather stations, altimeters, and vacuum sensors.
Contrarily, a gauge pressure sensor measures pressure relative to atmospheric pressure, which serves as the reference point. This sensor type finds frequent use in measuring pressure within pipes, tanks, and confined spaces. HVAC systems, pneumatic systems, and hydraulic systems often incorporate gauge pressure sensors.
Differential pressure sensors, as the name suggests, measure the disparity in pressure between two points. These sensors possess the capability to detect subtle pressure changes, making them suitable for applications such as flow measurement, filter monitoring, and fluid level measurement. HVAC systems, chemical processing plants, and medical equipment frequently rely on differential pressure sensors.
Are Absolute, Gauge and Differential Pressure Sensors Connected to My Circuit Differently?
Yes, absolute, gauge, and differential pressure sensors are connected to circuits differently.
Absolute pressure sensors are connected to circuits using a single pressure port. The pressure port is connected to the system where the pressure is to be measured.
Gauge pressure sensors are also connected to circuits using a single pressure port. The other side of the sensor, however, is connected to the atmosphere, while the pressure port is attached to the system where the pressure is to be monitored.
Differential pressure sensors are connected to circuits using two pressure ports. The two pressure ports are connected to the two points in the system where the pressure difference is to be measured.
What Are the Advantages of Absolute Pressure Sensor?
- Accurate Measurements: Absolute pressure sensors provide highly precise and accurate pressure measurements, since they measure pressure relative to a vacuum, they are suitable for applications that require precise readings.
- Versatility: Absolute pressure sensors are versatile and find application in various fields such as weather stations, vacuum, and barometers. They can accurately measure a wide range of pressures, spanning from low to high-pressure scenarios.
- High Sensitivity: With their high sensitivity, absolute pressure sensor detect even the smallest pressure changes. This characteristic makes them ideal for applications requiring close monitoring of pressure fluctuations.
- Wide Temperature Range: Absolute pressure sensor perform reliably across a wide temperature range, ensuring accurate readings even in extreme temperature conditions.
- Low Maintenance: Absolute pressure sensor do not necessitate regular calibration. This feature translates to cost-effectiveness and reduced time investment.
- Long Lifespan: Due to their robust design and resilience against external factors like mechanical stress, humidity, and vibration, absolute pressure sensor boast a long lifespan.
What Affect the Accurate Readings of Absolute Pressure Sensors?
The most common factors affecting the accuracy of absolute pressure sensors:
- Temperature: Fluctuations in temperature can lead to changes in the sensor’s output signal, potentially affecting accuracy. It is crucial to choose a sensor with an appropriate operating temperature range and take measures to minimize temperature-related impacts during operation.
- Humidity: Absolute pressure sensor can be sensitive to humidity changes, especially if they have a diaphragm or membrane. In such cases, humidity can cause the sensor’s mechanical components to expand and contract, affecting the readings.
- Vibration: Vibrations can introduce errors by affecting the mechanical components of the sensor. To maintain accuracy, it is important to minimize vibration levels in the sensor’s environment. Opting for sensors with high vibration resistance can also help mitigate these effects.
- Power Supply: The accuracy of the sensor can be influenced by the voltage supply used to power it. Ensure that the power supply voltage remains within the recommended range provided by the manufacturer to maintain accurate readings.
- Mechanical Stress: Mechanical stress from the installation method or external forces can cause deformation or damage to the sensor, leading to errors in the readings.
- Manufacturing Tolerances: Manufacturing tolerances can impact the accuracy of the sensor. To maximize accuracy, select sensors with high precision and work with reputable manufacturers known for producing high-quality sensors.
Absolute pressure sensor find utility in numerous applications, and selecting the appropriate sensor for your project is crucial, considering the varying requirements for accuracy and sensitivity. Fortunately, choosing a sensor that meets your precise needs can be a straightforward process. CFSensor offers a diverse range of high-quality sensors, ensuring you have ample options to explore. We encourage you to research our offerings and select from our lineup based on your specific requirements.