Design and Manufacture of Automotive Pressure Sensors

April 1, 2001 By: Mark Parsons

As a rule, 80% of a product's final cost is established in the first 20% of the design effort. Understanding the necessary design practices beforehand can minimize cost and also improve your success rate in designing robust piezoresistive pressure sensors for the demanding automotive environment.

Among the more challenging tasks undertaken by sensor designers is the design and manufacture of reliable, robust piezoresistive sensors for the automotive market. Through years of trial and error, these designers have developed practices and techniques that have proved useful again and again for automotive applications. To enlighten and


Photo 1. Sensors mounted in an automobile engine compartment can experience temperatuares of –40ºC to 150ºC, heavy water spray, fluid spills, and severe mechanical vibrations.

inform those who work with this technology, the following discussion discloses several tricks of the trade.

If you've never designed such sensors before, the first task is to open the hood (bonnet to European designers) of a recent-model vehicle (your own, perhaps), and have a good look at the engine compartment (see Photo 1). That nest of wires, hoses, and connectors around the engine is one of the most severe environments a sensor can have. Consider the thermal shock to an engine-mounted sensor, operating above 100°C and sprayed suddenly with slushy, salty water at 70 mph. Other properties of this environment are just as severe:

  • Temperature: –40° C to 125° C (to 150 C for engine-mounted sensors)
  • Vibration: Severe to extreme
  • Sensing media: Fuels (mixed blends), oil, brake fluid, transmission fluid, and noxious vapors<
  • External media: Water and saltwater spray, oils, brake fluids, solvents, and fuels
  • Thermal shock: High-temperature operation plus frequent cold-water splashing
  • EMI: 2 MHz to 2 GHz radiated exposure at 200 V/m

Sensors in the passenger compartment have much less exposure to fluids and solvents, but are subjected to low temperatures, water, and EMI:

  • Temperature: –40° C to 85° C
  • Vibration: Reduced levels
  • Sensing medium: Air, typically
  • External medium: Water spray
  • Thermal shock: Reduced rate of change
  • EMI: 2 MHz to 2 GHz radiated exposure at 200 V/m

For either environment, the sensor should have:

  • Reliability: 100% operational, every time, all the time
  • Lifetime: 10–15 years, sometimes expressed in terms of mileage (100 K/150 K) as well
  • Low cost: Automotive is among the most cost-sensitive of markets

To ensure that a sensor will meet customer expectations for performance, its specification and related test documents should attempt to capture representative stresses and operating conditions. You should read and comprehend these documents, but remember they are only a best attempt to represent the sensor's operating environment. Successful designs are based on proven concepts, materials, and circuits. Any connector under the hood, for example, represents decades of engineering work in design, materials, and production technology. Similarly, the sensors accepted for use in late-model production vehicles only a couple of years ago are available for your review. You can study the technology, the materials, and even the assembly techniques.

Automotive technical repair guides identify the sensors and wiring for most of today's vehicles. For example, vehicle shop manuals for late-model vehicles are available from most dealerships and auto-part stores (see Figure 1).


Figure 1. A typical automotive shop manual will show the sensor electrical wiring connections with pinout information, media connections and porting, and location on the vehicle.

They include drawings, photos, and wiring voltage levels. You can buy a sensor from an auto parts retailer, take it apart, study it, and ask yourself why it's made the way it is. Talk with automotive design experts in your own organization and try to distinguish among their opinions, rules-of-thumb, hard evidence, and data. Also, consider what new requirements the customers are asking for, what performance, cost, or reliability gains they are trying to realize, and whether these requirements represent a logical progression from what they are currently doing. This orientation may open your mind and lead to innovative thinking "out of the box."

In resolving problems in an existing design, you benefit from rereading the specifications and understanding the operating environment. Several specifications are important for a typical automotive sensor (see Figure 2).


Figure 2. For every vehicular sensor, there are several customer and device specifications that detail the expected operating characteristics and environmental factors.

Is the problem related to a particular specification or test? If possible, generate an exact description that focuses your investigation. Be specific, and include data that show good vs. bad, or issue vs. no issue. Interesting anomalies and other artifacts that could derail your investigation should be assessed for relevance and binned accordingly. That is, they should be saved and incorporated in the investigation, tagged as unknown, or simply tossed aside for a later investigation. The basic reasons for concern with an existing device involve issues of design, manufacturing, and spec vs. use.

If the design isn't solid, it might not support the customer's expectations. For example, a die-attach adhesive with reduced adhesion at elevated temperatures may not be strong enough to hold the die in place during vibration. Or a circuit design may have insufficient tolerance for ESD during vehicle assembly or service. In either case, the system can fail in the field after passing its qualification and design validation stress tests. Remember the statistics: a few select devices were tested for design robustness, but hundreds of thousands or millions were produced and field tested. Most design issues can be avoided with a careful design review and reasonable simulations.

A key discipline in sensor design lies in identifying all the significant characteristics, i.e., those that result in a perfect function if implemented within specifications. Such characteristics should be tracked during manufacturing using statistical process control (SPC). For a stable manufacturing process, no testing is required if you can ensure that each significant characteristic is within the limits set by SPC. These limits are quite different from specification limits. If the significant characteristics are within spec, then testing the sensor is simply a waste of time.

Practical considerations sometimes force the testing of sensors. Calibrating a sensor for pressure and temperature performance is usually more cost effective than specifying every subassembly to the degree necessary to enable blind assembly and shipment. (Manufacturing never reaches a state of complete flawlessness, regardless of the level of continuous improvement applied.) Knowing the significant characteristics and tracking them with SPC reduces the level of test and calibration necessary, thereby improving the cycle time, yield, and, ultimately, cost.

Missing a solder joint, improperly mixing a multipart epoxy, or installing an out-of-spec subassembly can undermine the best of manufactured devices by blocking the full intent of its design. Because such manufacturing issues can arise thousands of times per day or even per hour, they compel design, product, and process engineers to remain at the manufacturing plant overnight and during the weekends. Time-to-resolution is of the essence. Thousands of assembly employees are waiting for each component downstream in the vehicle-assembly line, and stopping the flow can cost upwards of $1 M per day.

An executive at a major automotive supplier has said, "For every bad component returned from the customer, there are a dozen more already in the manufacturing bone pile." The "bone pile" is the fallout from test and inspection during manufacturing, and failed parts are simply those with testable parameters outside the test limits (test limits include the specification limit, less the guard bands for gauge and repeatability).

How many devices encroached on the test limits but did not go over the edge? More important, why did they encroach in the first place? What changed? W. Edwards Deming made a career of asking these questions, and he revolutionized manufacturing by integrating it with SPC [1]. Parts close to the edge limit differ from the norm, and possibly differ in some way from the design intent. Is that change or difference stable? Will it change later with time or temperature and cause failures in the field? If every component that failed a test or inspection could be analyzed to find the root cause of its failure, then by correcting root causes you can achieve a robust and fine-tuned manufacturing process. Every component in the bone pile represents a story of process variances, material variances, and yet-undiscovered significant characteristics.

Other failures involve the product's definition vs. its actual use. If, for example, a sensor specified to operate at 0–50 psi is exposed to 60 psi in practice, then its failure can be attributed to a poorly defined specification. In a more subtle case, a sensor is specified to operate in the presence of automotive gasoline and methanol. The design validation test includes exposure to gasoline and to methanol under defined conditions of time, temperature, etc., but the sensor fails in the field from an apparent exposure to gasoline. In fact, the exposure was to a blend of methanol and gasoline in a ratio that proves more detrimental to materials than does gasoline or methanol alone. Therefore, the specification and test definition that attempted to capture real-world conditions was flawed or ill-worded. The sensor met its own specification, but not the customer's expectations.

Because the many cases of spec definition vs. use are difficult to resolve late in a sensor's design cycle, you should read the specifications and test requirements and note the actual intended operating environment of the sensor. For each specification item and test condition, ask yourself why it is included, and what actual condition of operation is being addressed. What is the result or the implication of not meeting this specification?

To resolve design and manufacturing issues, embrace the eight-discipline (8-D) problem-solving technique. The 8-D process was developed years ago by a major automotive manufacturer, with the goal of devising an effective way to determine root causes and corrective actions. The eight disciplines are:

  1. Problem description
  2. Containment actions
  3. Discovery of root cause
  4. Verification of root cause
  5. Permanent corrective actions
  6. Verification of permanent corrective actions
  7. Recurrence prevention
  8. Congratulations to the team

This problem-solving technique forces the removal of personal opinions and gut feeling statements, and brings in facts and data. The quality control executive director at Ford's Electronic Division was renowned for saying in 8-D review meetings, "In God we trust, all others bring data." It works. Keep the problem description clear and concise, to the extent of listing the serial numbers for affected units or vehicles. If immediate adjustments to process or design are used as a temporary way to maintain quality shipments, list them as containment actions. These will be removed and/or supplemented with permanent corrective actions as soon as they become available.

The root cause will be a final and concise statement about what design, manufacturing, or specification vs. use issue produced the problem. Before the permanent corrective actions are released into production, a verification plan must be developed and executed as part of the verification of permanent corrective actions sequence. Recurrence prevention is critical in preventing history from repeating itself.

Finally, congratulate your team. As simple as it is, this is the step most often overlooked. It provides two important results. The team is recognized for having identified and resolved a non-trivial issue, and the congratulations signal a closure of work on that issue, a disbanding of the team, and permission to return to normal duties.

This problem-solving process is an interesting journey of discovery regarding your sensor product and manufacturing process. If you keep an open mind to the possibilities and are confident enough to admit you don't have all the answers all the time, then each problem can become an interesting educational experience. Richard Feynman, winner of a Nobel prize in physics, summed up the pleasure of finding things out: "The . . . thrill, the . . . awe, and mystery come again and again when we look at any problem deeply enough. With more knowledge comes deeper, more wonderful mystery, luring one on to penetrate deeper still. Never concerned that the answer may prove disappointing, but with pleasure and confidence we turn over each new stone to find unimagined strangeness leading on to more wonderful questions and mysteries?certainly a grand adventure!" [2]

For piezoresistive sensor materials (silicone-gel and other protective coatings for sense elements and ICs, and die-attach epoxies), a


Figure 3. This cross-sectional view of a typical piezoresistive-based pressure sensor shows the media port for applied pressure, wire-bonded silicon die on substrate assembly, and various polymer materials.

few comments are in order. These materials surface again and again in sensor manufacturing, and using them requires knowledge of their initial properties, extended-life properties, and precautions for handling and mixing. A typical piezoresistive sensor assembly diagram is shown in Figure 3.

Die-attach epoxies come in many varieties and compositions; those commonly used for piezoresistive sensor mounting include soft-mount rubber-based adhesives, cyanoacrylate-based adhesives (with conductive silver-flake filler or nonconductive SiO2 filler), two-part epoxy blends, and silicone-based adhesives. Properties unique to each material address the issues of mechanical stress, temperature, chemical reactivity (or inertness), ease of manufacturing, and cost. The required chemical immunity depends on whether the die-attach is exposed to ambient conditions and contaminants, or to the medium whose pressure is being measured. Temperature should be considered not only during operation, but also during manufacture, storage, shipping, and the next level of assembly. Often, the most critical parameter is mechanical stress imparted by the die-attach material to the PRT element.

It's important to pay attention also to the many silicone- and epoxy-based materials that exhibit one of two different mechanical properties according to temperature. The material in question makes a transition between these properties at the glass-transition temperature, Tg [3]. Materials above this temperature tend to be stiffer, with (perhaps) a reduced thermal-expansion


Figure 4. Polymer materials can undergo significant changes in material properties as they pass through their glass-transition phase temperature, Tg.

coefficient; below, they tend to be more soft and supple. This property is usually apparent as a bow or curvature in the offset or sensitivity vs. temperature measurement (see Figure 4), and becomes apparent when you are generating a temperature step profile from lowest to highest. Because any kink or inflection in the curvature indicates change in a material property, you must in effect design with two different materials. As if that weren't enough, the Tg for two-part epoxies depends on the ratio of the two parts that are being mixed. Material properties for the final design are therefore a function of the two-part measuring and mixing process.

The characteristics of protective coatings for sense elements and ICs also have an influence. Those in contact with the sensing diaphragm can cause hysteresis with applied pressure and temperature, temperature-related changes in sensitivity and offset, output drift with time, and output creep.

Silicon has wonderful mechanical properties for the manufacture of reliable and repeatable sensors, but the introduction of die-attach materials and protective coatings can degrade the sensor's performance. To counter this effect, you should know how the material can be altered during manufacture by variations in the mix ratio, the effects of aging, exposure to air prior to curing, the cure time and temperature, etc. The material chosen for prototyping will likely be different from that used in the one-millionth sensor produced.

Some simple hints can make the electronics portion of your sensor design more robust. In general, a piezoresistive sense element is mounted on a substrate, which in turn is mounted to a housing or sensor body (see Figure 5).


Figure 5. A typical pressure sensor assembly contains one or more active silicon ICs, passive resistor and capacitive devices, and mechanical components.

Ducts within the housing serve to guide a fluid medium to the active portion of the sensor element. The substrate contains the signal conditioning IC (shown as a die in this case) and several discrete electrical components, and also provides electrical paths to the connector, to both receive power and give access to the output signal. The connector is typically a 3-wire type that carries a voltage analog of the pressure being measured. Basic circuit-layout principles give the best performance for a given schematic design:

  • Keep the electrical wiring connections between the IC and sense element as short as possible.
  • Do not intermingle the sense element's printed wiring traces with others, especially with digital clock traces and analog out traces.
  • Keep a decoupling capacitor of 0.1 µF (or recommended value) as close to the IC as possible, with minimal printed wiring interconnects.
  • Fill all remaining printed wiring surfaces with ground plane.
  • Place the ESD/EMI capacitors as close to the connector pins as possible.
  • If the circuit floats in a conductive housing that is electrically connected to the printed wiring circuit, connect the case to circuit ground with a resistive path.
  • For all ICs, tie the unused inputs to VDD or GND as appropriate, either directly or through a resistor.
  • Buffer the power input with a low-impedance resistor and capacitor, as close to the connector as possible. If possible, combine this filter capacitor with the ESD/EMI capacitor.
  • Protect the passivation layers for the IC and sense element. Any compromise of the IC passivation is reason to scrap the as-

  • If possible, ground the IC-mounting paddle with a conductive die-attach material.
  • If possible, electrically insulate the sense element from the case or pressure port.

If you are willing to devote the time, you can learn to debug analog sensor circuits. Most anomalies can be resolved quickly:

  • Check the power supplies.
  • Check the clock.
  • Check the memory.
  • Check where the test equipment is referenced and grounded.

Often, an apparent sensor anomaly is actually a good sensor operating in a bad environment. To be certain that the problem lies with the sensor itself, you can save hours of time and frustration by checking and double-checking its electrical and mechanical inputs. Further tips and good circuit-debugging procedures can found in Reference 4.

In debugging one faulty sensor (fallout from the line, for example), you can take courage from knowing that several thousand supposedly identical units have worked just fine. Therefore, when each component is connected and operating properly you can be sure the device will also work properly. This assurance is absent when debugging a first-time prototype, in which no circuit like it has ever been produced or demonstrated to work, so the challenge is to note how the sensor at hand differs from its several thousand precursors.

Sensor repeatability is everything. No amount of electronics can correct a sensor whose responses to temperature and pressure are unpredictable. There are several time-tested tricks for uncovering the causes of nonrepeatability in sensors, but you must decide which ones apply to your sensor assembly:

  • Slow temperature-step cycling
  • High-temperature soak
  • High-temperature soak, pressure hysteresis check
  • Power supply rejection test over temperature

By stepping temperature in small increments, from the lowest to the highest extreme, slow temperature-step cycling measures the variation of offset and span over temperature. Most sensors are tested at 25° C, at –40° C, at 125° C (or 85° C), and once again at 25° C. Known as the tri-temperature test, this procedure assumes that the sensor exhibits a smooth and continuous behavior at the intermediate temperature points.

But what really happens in between? Try this test on any good sensor: Cycle the temperature from room temp to cold, to hot, to cold, to hot, and back to room in 15° C increments, measuring the sensor response at each level. If the sensor is rated –40° C to 125° C, try temperature cycling beyond these limits, say from –55° C to 150° C. Do offset and span follow the same curve on each cycle, or does each cycle produce a different curve? This test exceeds the sensor's specified operating range, but it would be nice to know that no sudden, catastrophic failures occur just outside that range.

As for reliability, the behavior of sensor outputs at the extremes is just as interesting as a failure. Do the curves exhibit a significant inflection near or just beyond the operating temperature limit? What material or electrical property has changed or become dominant to cause this inflection? Inflections often begin within the normal operating range, indicating that a polymer material entered the glass phase via the glass transition temperature described earlier. Were alternate properties (e.g., temperature coefficient, Young's modulus) considered in the original design? When the device comes out of the glass phase, does it return to its original stress level and/or position? If not, then hysteresis with temperature may be present in the output.

The high-temperature soak test evaluates material stability. Starting at 25° C, verify sensor operation, then monitor the sensor output while quickly running the temperature to its highest operating level or beyond. Record the output for several hours while maintaining the high temperature. Output changes during this hold time indicate either an output variance due to thermal gradients across the sensor as the assembly comes to equilibrium at the elevated temperature (not so interesting), or material creep (much more interesting), which occurs when materials respond to stress by relaxing or moving to a less stressed condition.

Which material is creeping? Check the plastics and polymers. To identify the culprit, build a sensor using a different material (such as a protective coating), or one using more or less of the same material, or one that lacks the suspect material. Then, rerun the test on the modified unit and (ideally) a control unit as well, to see if the property changes.

The test of high-temperature soak with pressure-hysteresis check is similar to the above, but this procedure monitors the output while cycling pressure from minimum to maximum rather than monitoring the output over time. Does the pressure output signal follow the same curve each time? If not, some material may be relaxing or creeping due to the applied pressure. As a final test, set the pressure at maximum and hold it steady while returning the device to room temperature (or lower), and then reduce the pressure to zero. Does the output settle immediately to the zero value? Does it take several hours?or days?to return to the zero value recorded at the start of the test? If so, check the polymer materials. Also consider any mechanical assemblies in which two dissimilar materials are in contact with each other, causing a friction-slip condition.

For the test of power supply rejection over temperature, simply cycle the supply voltage from minimum to maximum at each of several different temperatures. Highest, lowest, and room temperatures are generally sufficient. Is the output change due to supply-voltage change the same at each temperature? Is the output significantly noisier (or quieter) when hot or cold? The IC will have different power supply rejection characteristics at different temperatures, but external capacitors (monolithic, tantalum, electrolytic) have pronounced effects on the base values of these characteristics. The circuit design should account for these factors by analyzing worst-case effects such as the variation of component values over temperature.

This test offers an opportunity to explore circuit properties such as the low-voltage operating point and startup-reset operation. At each temperature, slowly dial down the supply voltage until the sensor ceases to work. Then dial the voltage back up to its normal operating range and see if the circuit recovers and begins operating. The procedure tests the design for robustness to power supply anomalies over temperature. On the other hand, a check of high-voltage operating capability is not recommended because that test is usually a sure way to let smoke out of an IC.

The last point on reliable sensor production concerns change, which is arguably the main problem in high-volume automotive manufacturing. Because change generally begets trouble, it is dreaded and feared by most automotive manufacturing engineers with more than a few years in the business. Small changes that seem insignificant can bring to a halt the daily multimillion-dollar operation of a vehicle body and assembly plant. To illustrate this effect, the mathematician Benoit Mandlebrot proposed that a disturbance introduced by the wings of a single butterfly in China might cause a hurricane halfway around the world. So for any proposed change in manufacturing, materials, or components, be sure to create a verification plan that outlines the tests to be conducted in demonstrating the absence of adverse impacts. It should replicate all downstream vehicle-assembly and test operations, as well as vehicle road tests.

The common denominator for many change decisions is cost reduction. When change for the purpose of cost savings is forced on a well-designed product, and the consequences are neither understood or verified, the result can be a disaster. Nothing can beat ýhe cost performance of a product that is well designed (meaning that it represents a cost-effective selection and evaluation of materials and processes), and produced in a well-defined manufacturing process running at high yield. The best advice for a cost-reduction strategist is to focus on the next-generation design, and leave the existing product alone.


The design of your sensor product will depend predominantly on your manufacturing capabilities, intellectual property, company business plan, and your own technical knowledge. The practices described in this article will help you focus and expedite your sensor development process. Using a proven problem-solving methodology such as the 8-D process or your own corporate methods will greatly improve your ability to resolve issues with existing designs and even expedite the prototype-debugging phase of new sensor products. These practices will help make your next design the most reliable, robust, and cost-effective sensor yet.


1. M. Walton. 1986. The Deming Management Method, Perigee Books.

2. Richard Feynman. 1999. The Pleasure of Finding Things Out, Perseus Books:144.

3. R.A. Higgens. 1994. Properties of Engineering Materials 2nd Ed. Industrial Press Inc.:296-298.

4. Robert Pease. 1991. Troubleshooting Analog Circuits, Butterworth-Heinemann.

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