Silicon pressure sensors can be categorized into two main types: amplified and un-amplified.

Amplified silicon pressure sensors integrate advanced signal conditioning and amplification circuitry directly on the chip, delivering a robust, standardized output signal that simplifies system integration.

In contrast, un-amplified silicon pressure sensors provide a raw, millivolt-level output, requiring external signal processing.

Understanding the unique characteristics and trade-offs between amplified and un-amplified silicon pressure sensors is crucial in selecting the optimal solution for a given application.

So, amplified or un-amplified silicon pressure sensor, how to choose?

Challenges of raw piezo-resistive sensor output

Piezo-resistive pressure sensors based on silicon diaphragms inherently produce a very low-level output signal, typically in the millivolt range. This raw sensor output poses several challenges that need to be addressed.

Low Signal-to-Noise Ratio

• The millivolt-level sensor output is vulnerable to electrical noise, which can significantly degrade the measurement accuracy and stability.
• Without proper signal conditioning, the sensor’s useful signal can be easily obscured by background noise, making it difficult to achieve reliable pressure readings.

Temperature Sensitivity

• The piezo-resistive elements in silicon sensors exhibit a strong temperature dependence, leading to significant output drift as the operating temperature changes.
• Unconditioned, the sensor output can vary by 10-20% or more over the typical operating temperature range of -40°C to +125°C.

Impedance Matching

• The high output impedance of the raw piezo-resistive sensor (typically in the kΩ range) can create challenges in interfacing with downstream electronics, such as analog-to-digital converters (ADCs) or microcontrollers.
• Improper impedance matching can result in signal attenuation, waveform distortion, and increased susceptibility to electromagnetic interference (EMI).

Importance of on-chip signal processing

To overcome the challenges of raw piezo-resistive sensor output, it is crucial to integrate signal conditioning and amplification circuitry directly on the sensor chip. This on-chip integration offers several key benefits

Improved Signal-to-Noise Ratio

• The integrated amplification circuits can boost the sensor output by a factor of 100 or more, significantly improving the signal-to-noise ratio and enhancing the overall measurement accuracy.
• Specialized filtering techniques, such as correlated double sampling, can further reduce the impact of electrical noise.

Temperature Compensation

• On-chip signal processing allows for the implementation of advanced temperature compensation algorithms, which can minimize the output drift caused by changes in operating temperature.
• This compensation can typically reduce the temperature-induced error to less than 0.25% of full scale over the entire operating temperature range.

Impedance Matching and Signal Buffering

• The integrated amplification circuits provide a low-impedance output, which simplifies the interface with downstream electronics and reduces susceptibility to EMI.
• This buffering also ensures that the sensor output can be driven over longer cable lengths without significant signal degradation.

However, some applications may have unique signal processing requirements that are better suited for external, custom-designed conditioning circuits rather than the integrated amplification in amplified sensors. In such cases, un-amplified sensors, with mv output signal, will provide the flexibility to leverage specialized signal processing techniques.

Types of integrated amplification circuits

Various amplification circuit topologies can be implemented on the silicon pressure sensor chip, each with its own advantages:

Instrumentation Amplifiers

• Instrumentation amplifiers are widely used in amplified silicon pressure sensors, offering high input impedance, high common-mode rejection ratio, and excellent linearity.
• Example: An instrumentation amplifier with a gain of 100 and an input offset voltage of 50 μV can provide a 0-5 V output for a 0-100 mV sensor input.

Operational Amplifiers (Op-Amps)

• Op-amp-based amplification circuits offer flexible design options, allowing for customized gain, offset, and filtering configurations.
• These circuits can be optimized for specific sensor requirements and integrated onto the same silicon substrate.

Application-Specific Integrated Circuits (ASICs)

• Highly specialized ASIC designs can integrate advanced signal processing functionalities, such as digital calibration, temperature compensation, and diagnostic features.
• ASICs can provide a turnkey solution for amplified silicon pressure sensors, offering a higher level of integration and optimization.

Sensor Packaging and Environmental Ruggedness

Hermetic packaging for media compatibility

Amplified silicon pressure sensors are designed to operate in a wide range of industrial and commercial environments, often exposed to harsh media conditions. To ensure reliable and durable performance, these sensors are typically housed in hermetic packages that provide exceptional media compatibility.

The hermetic packaging employs techniques such as metal-to-metal or metal-to-ceramic sealing to create a truly airtight and waterproof enclosure. This hermetic seal prevents the ingress of liquids, gases, or other contaminants that could potentially damage the sensitive silicon sensing elements and integrated electronics.

For example, an amplified silicon pressure sensor with a stainless steel housing and a laser-welded metal diaphragm can provide excellent resistance to a variety of media, including oils, fuels, hydraulic fluids, and even corrosive chemicals, making it suitable for applications in the oil and gas, industrial automation, and automotive industries.

Techniques for vibration and shock resistance

Amplified silicon pressure sensors are often deployed in environments with significant levels of vibration and shock, such as industrial machinery, off-road vehicles, and heavy equipment. To withstand these harsh conditions, specialized packaging and mounting techniques are employed.

One common approach is the use of a robust, low-profile metal housing that is designed to minimize the transfer of vibrations to the sensitive sensing elements. Additionally, the sensor package may incorporate advanced damping mechanisms, such as elastomeric gaskets or O-Ring , to absorb and dissipate the energy from shock and vibration.

For example, an amplified silicon pressure sensor with a vibration resistance of 30 g (rms) and a shock resistance of 150 g would be suitable for applications with moderate to high levels of vibration and shock, commonly found in industrial and automotive environments.

Operating temperature range (-40°C to +125°C)

Amplified silicon pressure sensors are designed to operate reliably across a wide temperature range, typically from -40°C to +125°C (-40°F to +257°F). This broad operating temperature range is achieved through a combination of advanced materials, specialized packaging, and integrated temperature compensation circuitry.

The use of high-performance silicon, specialized adhesives, and robust packaging materials ensures that the sensor’s mechanical and electrical properties remain stable even under extreme temperature conditions.

Furthermore, the integrated signal conditioning and amplification circuits incorporate temperature compensation algorithms that actively correct for any temperature-induced output drift, maintaining consistent and accurate pressure measurements throughout the operating temperature range.

For instance, an amplified silicon pressure sensor with an accuracy specification of ±0.25% of full scale over the -40°C to +125°C temperature range would be well-suited for applications that require reliable pressure monitoring in demanding environments, such as industrial process control, automotive systems, and aerospace equipment.

Analog vs. Digital Amplified Silicon Pressure Sensors

Analog Output Sensors (Voltage, Current):
Amplified silicon pressure sensors can provide analog output signals, typically in the form of voltage or current. These analog interfaces are well-established and widely compatible with a variety of industrial control systems and data acquisition equipment.

Voltage Output:

• Voltage output sensors commonly provide standardized output ranges such as 0-5 VDC, 0-10 VDC, or ratiometric 0.5-4.5 VDC.
• For example, an amplified silicon pressure sensor with a 0-10 VDC output and a pressure range of 0-100 psi (0-689 kPa) would have a sensitivity of 0.1 V/psi (0.0145 V/kPa).
• Voltage output sensors are well-suited for applications where the control system or data acquisition hardware has high-impedance voltage inputs.

Current Output:

• Current output sensors typically offer a 4-20 mA signal, which is a widely adopted standard in industrial automation.
• This current-based output is less susceptible to noise and can be transmitted over longer distances without significant signal degradation.
• For instance, an amplified silicon pressure sensor with a 4-20 mA output and a pressure range of 0-500 psi (0-3.45 MPa) would have a sensitivity of 0.032 mA/psi (0.0046 mA/kPa).
• Current output sensors are advantageous in applications where the control system has current-based inputs or when the sensor needs to be located far from the control equipment.

Digital Output Sensors (I2C, SPI, UART):

In addition to analog outputs, amplified silicon pressure sensors can also provide digital interface options, such as I2C, SPI, or UART communication protocols.

I2C (Inter-Integrated Circuit):

• I2C is a widely used serial bus interface that allows for direct connection to microcontrollers and embedded systems.
• It enables bidirectional communication, allowing for sensor configuration, calibration, and diagnostic data exchange.
• I2C-based amplified silicon pressure sensors are well-suited for applications that require integrated sensor-to-microcontroller communication, such as in industrial automation and IoT (Internet of Things) devices.

SPI (Serial Peripheral Interface):

• SPI is a serial communication protocol that provides a high-speed, synchronous data transfer interface.
• SPI-based amplified silicon pressure sensors can offer faster data rates compared to I2C, making them suitable for applications that require rapid pressure data acquisition, such as in automotive or aerospace systems.

UART (Universal Asynchronous Receiver-Transmitter):

• UART is a simple, asynchronous serial communication interface commonly found in embedded systems and industrial controllers.
• UART-based amplified silicon pressure sensors can provide a direct interface to serial communication ports, simplifying integration into legacy systems or applications that require a straightforward serial data link.

Advantages and Use Cases:
Analog and digital output amplified silicon pressure sensors each have their own advantages and use cases:

Analog Output:

• Simplicity of integration with legacy analog control systems
• Straightforward signal conditioning and processing
• Suitable for applications with distance constraints or electrical noise concerns

Digital Output:

• Enables advanced sensor configuration and diagnostics
• Facilitates integration with microcontrollers and digital control systems
• Provides higher noise immunity and data integrity over long cable runs
• Ideal for applications requiring sensor networking, remote monitoring, or IoT integration

Advanced Features of Amplified Silicon Pressure Sensors

On-board Diagnostics and Self-testing

Amplified silicon pressure sensors can be equipped with advanced on-board diagnostics and self-testing capabilities to enhance their reliability and fault detection. These features are particularly valuable in mission-critical applications where constant monitoring and early detection of potential issues are crucial.

Examples of on-board diagnostics include:

• Sensor element integrity checks: Monitoring the health of the piezo-resistive sensing elements for any open or short circuit conditions.
• Supply voltage monitoring: Ensuring the sensor is operating within the specified power supply voltage range.
• Temperature sensor integration: Tracking the internal sensor temperature to enable advanced temperature compensation.

• Overpressure and burst pressure detection: Alerting the system when the applied pressure exceeds the sensor’s safe operating limits.

The self-testing functionality allows the sensor to perform periodic, automated checks of its internal circuitry and signal processing components. This can include verifying the operation of the amplification circuits, analog-to-digital converters, and digital communication interfaces.

Digital Calibration and Compensation

Amplified silicon pressure sensors often incorporate advanced digital calibration and compensation algorithms to enhance their accuracy and stability over a wide range of operating conditions.

Digital Calibration:

• The sensor’s output can be digitally calibrated during the manufacturing process to correct for any inherent non-linearity, hysteresis, or offset errors.
• This digital calibration can achieve accuracy levels of ±0.1% to ±0.25% of the full-scale output, surpassing the performance of traditional analog calibration methods.

Temperature Compensation:

• Integrated temperature sensors and compensation algorithms can dynamically correct the pressure sensor’s output for changes in ambient temperature.
• This can reduce the typical temperature-induced error from 10-20% down to less than 0.25% of the full-scale output over the entire operating temperature range.

Programmable Output Scaling and Offset

Amplified silicon pressure sensors may offer the ability to program the output scaling and offset through digital interfaces, such as I2C or SPI.

Output Scaling:

• The sensor’s output can be scaled to match the specific pressure range requirements of the application, allowing for a more optimized use of the available output span.
• For example, an amplified silicon pressure sensor with a 0-100 psi (0-689 kPa) range could be scaled to provide a 0-5 VDC output for 0-50 psi (0-345 kPa).

Output Offset:

• The sensor’s output can be digitally adjusted to provide a custom offset, which can be useful for applications where a specific zero-pressure reference is required.
• This programmable offset can be particularly beneficial in applications where the sensor needs to be integrated into existing systems with specific input requirements.

These advanced features, such as on-board diagnostics, digital calibration, and programmable output scaling, enable amplified silicon pressure sensors to deliver exceptional performance, flexibility, and reliability, making them well-suited for a wide range of demanding industrial, automotive, and commercial applications.

Conclusion

In conclusion, the comprehensive exploration of amplified silicon pressure sensors has unveiled their pivotal role in transforming the world of industrial and commercial pressure measurement. These advanced sensors seamlessly integrate sensing and signal conditioning capabilities, delivering a robust, standardized output that simplifies system integration and enhances overall performance.

By delving into the nuances of silicon piezo-resistive sensing, integrated signal processing, and specialized packaging, we’ve gained a deeper understanding of the technical innovations that underpin amplified silicon pressure sensors. The ability to withstand harsh environmental conditions, provide exceptional accuracy and stability, and offer flexible analog and digital interfaces has positioned these sensors as the preferred choice for a wide range of mission-critical applications, from industrial automation to automotive systems and beyond.

As the demand for reliable and high-performance pressure measurement continues to grow, amplified silicon pressure sensors stand at the forefront, offering engineers and system designers a versatile and future-proof solution to address the evolving needs of their industries. The advanced features, such as on-board diagnostics, digital calibration, and programmable output scaling, further solidify the position of amplified silicon pressure sensors as a cornerstone of modern pressure sensing technology.

When selecting a ceramic pressure sensor for your application, one of the key considerations is whether to choose an amplified ceramic pressure sensor or unamplified type. Each option has its own set of advantages and trade-offs, and the choice will depend on the specific requirements of your system. In this blog post, we’ll dive deep into the technical details of unamplified and amplified ceramic pressure sensor to help you make an informed decision.

Unamplified ceramic pressure sensor

Sensing Element

Unamplified ceramic pressure sensor typically uses piezo-resistive or strain gauge sensing elements that are directly fabricated onto the ceramic or SS316 diaphragm. These sensing elements generate a small electrical signal through Wheatstone bridge, typically in the millivolt range, in response to the applied pressure.

Output Signal

The output signal from an un-amplified ceramic pressure sensor is a raw, unprocessed voltage or current signal that directly corresponds to the applied pressure. This raw signal requires additional signal conditioning and amplification before it can be used by the control system or data acquisition equipment.

Applications

Unamplified ceramic pressure sensor s are often used in applications where the signal processing and amplification can be handled by the end-user’s own electronics or control system. They are generally more cost-effective compared to amplified sensors, as the signal conditioning and amplification circuitry is not integrated into the sensor itself.

Example Specifications:

• Output Signal: 0-100 mV
• Pressure Range: 0-100 psi (0-689 kPa)
• Accuracy: ±0.5% of full scale

Model recommendation

• ESS501: Monolithic Ceramic Pressure Sensor Cell
• ESS502: Flush Diaphragm Ceramic Pressure Sensor Cell

Amplified ceramic pressure sensor

Integrated Amplification

Amplified ceramic pressure sensor incorporate signal conditioning and amplification circuitry directly into the sensor housing or package. This integrated circuitry takes the raw, millivolt-level signal from the sensing elements and amplifies it to a higher-level, standardized output signal, such as 0.5-4.5V or 4-20mA or digital I2C.

Output Signal

The output signal from an amplified ceramic pressure sensor is a pre-conditioned and amplified voltage or current signal 0.5-4.5V or 4-20mA or digital I2C., (we will discuss details of these types output signal in next section) which can be directly interfaced with control systems, data acquisition equipment, or other industrial automation devices. This eliminates the need for additional external signal conditioning and amplification, simplifying the system integration and wiring requirements.

Applications

Amplified ceramic pressure sensor is preferred in applications where the end-user requires a readily available, plug-and-play pressure measurement solution. They are particularly useful in applications where the sensor needs to be placed in remote or hard-to-access locations, as the integrated amplification and signal conditioning simplify the installation and interface with the control system.

Example Specifications:

• Output Signal: 4-20 mA/0.5-4.5V/I2C
• Pressure Range: 0-500 psi (0-3.45 MPa)
• Accuracy: ±0.25% of full scale
• Supply Voltage: 12-36 VDC

Model recommendation

• ESS501-I/V-IIV: Monolithic Ceramic Pressure Sensor Module
• ESS502-I/V-IIC: Flush Diaphragm Ceramic Pressure Sensor Module

Types of Amplified ceramic pressure sensor

Aa above mentioned, the amplified ceramic pressure sensor offer a significant advantage over their unamplified counterparts by integrating signal conditioning and amplification circuitry directly into the sensor package. This integration eliminates the need for external signal processing, simplifying the integration and wiring requirements for your industrial automation or control system. However, when it comes to amplified ceramic pressure sensors, there are different types of signal outputs to consider.

Voltage Output Amplified

Output Signal

• Voltage output amplified ceramic pressure sensor s provide a standardized voltage signal, typically in the range of 0-5V, 0.5-4.5V, 0-10V, or even ±10V.
• This voltage output signal is directly proportional to the applied pressure, allowing for easy interfacing with a wide range of control systems and data acquisition equipment.
• Check out details: How to decide which voltage output is good for me?

Advantages

• Voltage output signals are widely accepted and understood, making them easy to integrate into existing systems.
• Voltage outputs are generally less susceptible to noise and interference, ensuring reliable signal transmission over longer cable runs.
• Voltage-based sensors often have a higher input impedance, allowing for simpler and more cost-effective signal conditioning circuitry in the end-user’s system.

Current Output Amplified

Output Signal:

• Current output amplified ceramic pressure sensors provide a standardized current signal, typically in the range of 4-20 mA or 0-20 mA.
• This current output signal is directly proportional to the applied pressure, allowing for easy integration with a wide range of industrial control and monitoring systems.
• Check out details: How to decide which analog output is good for me?

Advantages:

• Current output signals are less susceptible to noise and interference, making them more suitable for applications with long cable runs or in electrically noisy environments.
• Many industrial control systems are designed to directly accept current-based sensor inputs, simplifying the integration process.

Digital Output Amplified

Output Signal:

• Digital output amplified ceramic pressure sensors provide a digital communication interface, such as I2C, SPI, or UART, to transmit the pressure measurement data.
• These sensors often include additional features like on-board temperature compensation and digital calibration, enhancing the overall measurement accuracy and reliability.
• Check out details: How to decide which I2C output is good for me?

Advantages:

• Digital output signals allow for more advanced data processing and communication capabilities, enabling features like remote configuration, diagnostic information, and integrated temperature compensation.
• Digital interfaces facilitate easy integration with microcontrollers, industrial PCs, and other digital control systems, simplifying system architecture and reducing the need for analog-to-digital conversion.

• Digital output sensors can provide higher resolution and precision pressure measurements compared to analog voltage or current outputs.

Amplified VS Unamplified: Technical View

Un-amplified ceramic pressure sensor s offer a cost-effective solution for many industrial and commercial applications, while amplified ceramic pressure sensor s offer a plug-and-play solution for industrial automation and control systems, providing integrated signal conditioning and amplification to simplify installation and system integration, but selecting the right type requires a deep understanding of the technical specifications and how they align with your system requirements.

In this section, we are planning to discuss the most critical factors to consider, in technical views, when choosing pressure sensor, with a focus on linearity and accuracy, environmental compatibility, and system integration considerations.

Linearity

Linearity is a crucial specification that describes the sensor’s deviation from a straight-line response.

For un-amplified ceramic pressure sensor s, linearity error can range from ±0.5% to ±2% of the full scale.

For example, an unamplified ceramic pressure sensor with a linearity error of ±0.5% of full scale and a pressure range of 0-100 psi (0-689 kPa) would have a maximum linearity deviation of ±0.5 psi (±3.45 kPa) across the entire pressure range.

For amplified ceramic pressure sensor s, linearity error is typically much lower than unamplified sensors, ranging from ±0.1% to ±0.5% of the full scale.

For example, an amplified ceramic  pressure sensor with a linearity error of ±0.25% of full scale and a pressure range of 0-500 psi (0-3.45 MPa) would have a maximum linearity deviation of ±1.25 psi (±8.62 kPa) across the entire pressure range.

Accuracy

Accuracy encompasses the combined effects of linearity, hysteresis, and repeatability. Unamplified ceramic pressure sensors typically have an accuracy specification of ±0.5% to ±1% of the full scale.

For example, an unamplified ceramic pressure sensor with an accuracy of ±0.5% of full scale and a pressure range of 0-500 psi (0-3.45 MPa) would have a maximum accuracy error of ±2.5 psi (±17.2 kPa) across the entire pressure range.

Amplified ceramic pressure sensor s typically have an accuracy specification of ±0.1% to ±0.5% of the full scale.

For example: An amplified ceramic pressure sensor with an accuracy of ±0.1% of full scale and a pressure range of 0-100 psi (0-689 kPa) would have a maximum accuracy error of ±0.1 psi (±0.69 kPa) across the entire pressure range.

Operating Temperature Range

Un-amplified ceramic pressure sensor s are designed to operate within specific temperature ranges, which can vary from sensor to sensor. A typical temperature range for an unamplified sensor might be -20°C to +85°C (-4°F to +185°F).

On the other hand, amplified ceramic pressure sensors are designed to operate within specific temperature ranges, which can vary from sensor to sensor. A typical temperature range for an amplified sensor might be -40°C to +125°C (-40°F to +257°F).

Vibration and Shock Resistance

Unamplified and amplified ceramic pressure sensor s are often used in industrial environments with potential vibration and shock,

For example:

An unamplified ceramic pressure sensor with a vibration resistance of 20 g (rms) and a shock resistance of 100 g would be suitable for applications with moderate to high levels of vibration and shock.

An amplified ceramic pressure sensor with a vibration resistance of 30 g (rms) and a shock resistance of 150 g would be suitable for applications with moderate to high levels of vibration and shock.

Wrap up

Today, we’ve covered a comprehensive understanding of both amplified and unamplified ceramic pressure sensors, delving into the key aspects that engineers and system designers need to consider when selecting the right sensor for their applications.

The primary distinction lies in the sensor’s signal conditioning and amplification capabilities. Unamplified ceramic sensors provide a raw, millivolt-level output signal that requires external processing, while amplified sensors integrate signal conditioning and amplification circuitry to deliver a standardized, plug-and-play output.

When choosing an unamplified sensor, critical factors include the sensing element technology (piezo-resistive or strain gauge), the output signal characteristics, linearity and accuracy specifications, environmental compatibility, and system integration requirements. Ensuring the sensor’s technical performance aligns with the application’s needs is essential for reliable and accurate pressure measurements.

In contrast, amplified ceramic pressure sensors offer enhanced linearity (±0.1% to ±0.5% of full scale) and accuracy (±0.1% to ±0.5% of full scale), broader environmental compatibility, and simplified system integration. These sensors provide standardized voltage, current, or digital output signals that can be readily interfaced with industrial control systems, eliminating the need for external signal processing.

Understanding the trade-offs between amplified and unamplified sensors is crucial. Amplified sensors offer plug-and-play convenience and superior performance, but may come at a higher cost, while unamplified sensors can be more cost-effective but require additional signal conditioning resources.