The present invention relates to inertial sensors, and more particularly to packaging for inertial sensors.
It is known in the prior art to enclose micromachined (“MEMS”) inertial sensor in a package, to protect the inertial sensor from damage. Some inertial sensors are hermetically sealed to maintain a desired atmosphere and environment. A typical MEMS inertial sensor includes at least one movable component movably suspended above a substrate. The substrate and movable component face each other across a gap, and have dimensions that are large relative to the gap.
In the case of an accelerometer, the movable component may be known as a “beam.” The inertia of the beam will cause the beam to be displaced relative to the substrate when the accelerometer is subjected to an acceleration. The quantity of such displacement is a function of the acceleration, as well as the properties of the beam and its suspension system. The sensitivity of the accelerometer is a function of the displacement of the beam; the greater the displacement under a given acceleration, the greater the sensitivity of the accelerometer. Generally, therefore, the suspension of the beam is configured to allow maximum displacement of the beam while ensuring acceptable linearity.
In normal operation, the substrate and movable component do not come into contact. However, if the moveable component approaches the substrate or other surface, the opposing (or “facing”) surfaces may adhere to one another, in a phenomenon commonly known as “stiction.”
Stiction is a dominant failure mechanism in micromachined devices, and can arise in a variety of ways. Stiction may arise, for example, when interfacial forces between two opposing faces of a micromachined device exceed the restoring forces of the suspension system. The stiction forces may include capillary forces, chemical bonding, electrostatic forces, and van der Waals forces.
To reduce the risk of stiction, packing for MEMS devices typically leaves a generous gap between the movable component and the surface of the packaging.
In a first embodiment there is provided an accelerometer having a Q-factor of less than 2.0, the accelerometer including a substrate having a substrate surface; a movable mass suspended from the substrate, the movable mass having a first surface and a second surface opposite the first surface, the first surface facing the substrate surface and separated from the substrate surface by a first gap; a cap having a cap surface, the cap coupled to the substrate and forming a hermetically sealed volume with the substrate and enclosing the movable mass, wherein the second surface is opposite the cap surface and is separated from the cap surface by a second gap; and a gas filling the volume at a pressure of less than 1 atmosphere, the gas having a viscosity of less than 25.0 μPa·s, in which each of the first gap and the second gap being less than 10 um, such that the accelerometer has a Q-factor of less than 2.0.
In some embodiments, the gas is at a pressure below 0.5 atmospheres.
Some embodiments include at least one standoff on the cap surface, and in some embodiments the standoff is opposite the second surface when the movable mass is in a rest position.
Some embodiments include a frit between the substrate and the cap, the frit securing the substrate to the cap and forming a hermetic seal between the substrate and the cap.
Some embodiments also include a mesa, and a surface of the mesa is a part or portion of the cap surface, while in some embodiments the mesa includes two or more mesa portions.
Some embodiments include a number of standoffs around, or even on a surface of, a mesa.
In some embodiments, the substrate includes a mesa, and a surface of the mesa is a part or portion of the substrate surface. Some embodiments include one or more standoffs around the mesa portion of the substrate.
In another embodiment there is provided a method of fabricating an accelerometer having a Q-factor of less than 2.0, the method including the steps of providing a substrate having a substrate surface; suspending a movable mass from the substrate, the movable mass having a first surface and a second surface opposite the first surface, the first surface facing the substrate surface and separated from the substrate surface by a first gap; providing a gas around the substrate at a pressure of less than 1 atmosphere, the gas having a viscosity of less than 25.0 μPa·s; providing a cap, the cap having a cap surface; and mounting the cap to the substrate such that the second surface is opposite the cap surface and is separated from the cap surface by a second gap, and such that the substrate and cap form a hermetically sealed volume and enclose the movable mass and trap some of the gas within the volume, such that each of the first gap and the second gap is less than 10 um, and such that the accelerometer has a Q-factor of less than 2.0.
In some embodiments, the step of providing a gas around the substrate includes providing a gas around the substrate at a pressure of less than 0.5 atmospheres, the gas having a viscosity of less than 25.0 μPa·s.
In some embodiments, the cap includes at least one standoff on the cap surface, and in some embodiments the standoff is opposite the second surface when the movable mass is in a rest position.
In some embodiments, the method also includes providing a frit between the substrate and the cap, the frit securing the substrate to the cap and forming a hermetic seal between the substrate and the cap.
In some embodiments, the step of providing a cap further includes providing a cap having a mesa, and a surface of the mesa being a part or portion of the cap surface. In some embodiments, the mesa includes a plurality of mesa portions.
In some embodiments, the step of providing a cap further includes, providing a cap includes providing a cap that has two or more standoffs around the mesa.
In some embodiments, the step of providing a substrate includes providing a substrate having a mesa, and a surface of the mesa is a part or portion of the substrate surface. In some embodiments, the step of providing a substrate having a mesa further includes providing a substrate having two or more standoffs around the mesa.
The foregoing features of embodiments will be more readily understood by reference to the following detailed description, taken with reference to the accompanying drawings, in which:
Various embodiments provide an accelerometer in which the proof mass is encapsulated in a low-viscosity gas, and yet the accelerometer has a dampened response to shock acceleration, or dynamic acceleration, have a frequency component at or near the accelerometer's resonant frequency (fo). Embodiments are easy to manufacture, and provide the additional benefit that they can be fabricated without encapsulating a high-viscosity gas within the accelerometer. In addition, various embodiments provide an easy way to detect when a packaged accelerometer has lost its hermetic seal.
Typically, accelerometers are designed and manufactured to have a pronounced response to an applied acceleration at a frequency well below the accelerometer's resonant frequency, because such a response tends to desirably increase the sensitivity of the accelerometer, for example if the accelerometer is of the capacitive type. Generally, the greater the displacement of the beam, the greater the change in capacitance. For that reason, the suspension system in an accelerometer is typically configured to be sufficiently rigid so as to suspend the beam above a supporting substrate, but to be sufficiently compliant so as to avoid hindering the displacement of the beam. As such, the response of the accelerometer depends, in part, on the compliance of the accelerometer's internal suspension system.
In some applications, such as those in which higher frequency, lower acceleration amplitude shock events occur regularly, an undesirable over-drive acceleration response may occur when the shock frequency is at or near the accelerometer's resonant frequency (fo). The term “shock frequency” refers to the frequency spectrum of a wave caused from one shock (i.e., a physical impulse). Such a wave may be a dynamic vibration wave, with frequency or frequency components that vary (e.g., in a non-linear system) depending on the properties of the accelerometer and the way the wave interacts with the accelerometer and its media/environment. A shock event, in turn, may be a single shock, or multiple shocks. Even a single shock may have a frequency spectrum that includes the accelerometer's resonant frequency, or a harmonic of that resonant frequency, while multiple shocks may even occur at a frequency that includes the accelerometer's resonant frequency, or at a harmonic of that resonant frequency. In such scenarios, the sensor may fail to function properly or produce false alarm as the sensor moving structure could be stuck or damage, or to some lesser degree, send wrong output signal as if the much higher acceleration load apply. As such, in some applications, a dampened response is desirable. For example, sensors with a damping performance requirement for over-load protection are used in applications such as automotive and industrial fields where common shock events happen regularly, and have a frequency component at a frequency around the sensor's resonating frequency (fo).
To that end, an illustrative embodiment of a micromachined accelerometer 100 according to the present application is schematically illustrated in
When the accelerometer 100 is not subject to an acceleration, the beam 101 remains suspended above the substrate 102 in a position that may be known as its “nominal” or “rest” position, and does not move relative to the substrate 102. However, when the substrate 102 is subjected to an acceleration, for example in the +X direction, the inertia of the beam 101 causes a displacement of the beam 101 in the -X relative to the substrate 102. A finger 103 on the beam 101 forms a variable capacitor across gap 107 with a counterpart finger 104 on the substrate 102. The capacitance varies when the beam 101 moves relative to the substrate 102. The variable capacitance can be electronically processed to produce an electrical signal representing the displacement of the beam, and the signal therefore represents the acceleration.
In the accelerometer 100 of the embodiment of
The inventors have discovered that the behavior of a low-viscosity gas (including many common gases) in such a narrow gap is such that the gas acts to dampen motion of the beam, thereby producing a response to the near-fo shock frequencies (i.e., frequencies near the resonant frequency of the beam) that is less pronounced acceleration than in prior art accelerometers with larger gaps if filled with the same gas.
The accelerometer 100 of
One such concern is the risk of stiction. For example, ideally, the beam 201 remains suspended above the substrate 202 at all times; in other words, the motion of the beam 201 relative to the substrate 202 occurs within a plane above, and parallel to, the substrate. In some circumstances, however, the suspension system may allow the beam 201 to move towards the substrate 202 or cap 210 and become stuck. Such an extreme and undesirable displacement of the beam may be known as “jump shift.” For example, the bottom surface 201B of the beam 201 may become stuck to the opposing surface 206 of the substrate 202. Alternately, the top surface 201A of the beam 201 may become stuck to the opposing surface 210A of cap 210, for example when the accelerometer 100 is subject to an acceleration with a large acceleration vector normal to the plane of the top surface 206 of the substrate (i.e., in the Z direction), or during the packaging of the accelerometer, or when accelerometer is installed on a circuit board. In addition, contaminants between the beam 101 and substrate 102, such as moisture on one or both of the facing surfaces 105 and 106 of the beam 101 and substrate 102, may cause stiction or otherwise degrade performance of the accelerometer.
To reduce the risk of stiction, packing for MEMS devices typically leaves a generous gap between the movable component and the surface of a cap or other packaging, and between the beam and a substrate. In contrast to the embodiment in
Another concern arises in considering how to dampen the response of accelerometer 200. One way to moderate the response of an accelerometer is to encapsulate the accelerometer's beam in a cavity filled with high-viscosity gas, such as neon for example. The high-viscosity gas dampens the motion of the beam because it presents a resistance to beam motion. In practical terms, the high-viscosity gas presents a thick atmosphere through which the beam must move, and the very thickness of that atmosphere tends to resist the motion of the beam. However, the use of high-viscosity gasses is undesirable, in part because such gasses are not commonly used in semiconductor fabrication facilities. Providing such gasses therefore requires costs and efforts that make the fabrication facilities and processes more complicated and expensive. For example, to dampen the response of accelerometer 200, the volume 260 may be filled with such gases as air (having a viscosity of approximately 18) or argon (having a viscosity of approximately 22), to name but a few.
The accelerometers 100 and 200 may be compared and contrasted by considering their respective Q-factors (or “Q”). A system's Q-factor is a measure of its resonance characteristics. In other words, an accelerometer's suspended beam (e.g., 101, 201) may be forced to resonate by, for example, subjecting the accelerometer to a periodic acceleration. Although a beam does not resonate when detecting a linear acceleration, the compliance of the suspension system, and therefore the tendency of the beam to be displaced when subjected to acceleration, is correlated to the Q of the beam.
For a given accelerometer, the displacement of the beam (or alternately, the amplitude of the beam's cyclical displacement) will reach a maximum at a given frequency 301, which may be known as the “resonant” frequency (which may be designated as “fo”). For example, for an undamped accelerometer 200, the maximum displacement of the beam will occur at frequency fo, as schematically illustrated in
The Q of an accelerometer is then determined as the ratio of the resonant frequency (fo) divided by difference (Δf or delta-f) 310 between the upper 3 dB frequency and the lower 3 dB frequency. The graph of an accelerometer's frequency response for a one accelerometer is schematically illustrated in
A graph 400 comparing the Q of various damped accelerometers is presented in
As shown, the Q of the accelerometers tends to decrease with increasing pressure of the fill gas. Conversely, at low pressures, an accelerometer's Q tends to increase.
For example, for a prior art accelerometer may have a gap of 20 um between the inner surface of its cap and the facing surface of its beam (e.g., gap 250 in
In contrast, the Q of an exemplary embodiment of an accelerometer, e.g., accelerometer 100, may be held below 3.5 using even low-viscosity gas, and even at pressures as low as 0.2 atmospheres, as illustrated by curve 450 in graph 400 for example. By way of example, the gas in accelerometer 100, which yields the Q curve 450, may be nitrogen. The dampening provided by the small gap or gaps of accelerometer 100, as described above, is distinct from prior art accelerometers, even when the same gas (e.g., nitrogen) is used.
The relationship of Q to pressure of curve 450 in
Generally, for accelerometers with gap dimensions of less than 10 um, a smaller gap or gaps will yield lower Q at a given pressure. As such, for an accelerometer with given gap dimensions, the selection of the pressure of the fill gas can be reduced to raise the Q or increased to lower the Q. Similarly, for an accelerometer with a given gas pressure, gap dimensions may be selected within a range of up to 10 um to increase or lower the Q. In short, to produce a desired Q, a desired gap or gaps of less than 10 um may be specified, and the pressure will then be determined by the Q and the gap, or a desired pressure may be specified, and the gap dimensions will be determined by the Q and the pressure.
An additional advantage of the accelerometer 100 is that the pressure of the fill gas can be set and maintained at a low level (e.g., as low as 0.2 atmospheres in the example of curve 450 in
A number of alternate embodiments are schematically illustrated in
In various embodiments, the intermediate layer 502 may be solder, or a frit such as a glass frit, or other medium capable of hermetically securing the cap 501 to the substrate 102.
Although accelerometers 100 and 500 have caps with planar inner surfaces 110A and 501A, that is not a limitation of all embodiments. In some embodiments, the narrow gap may be created by a portion that protrudes from a surface facing the beam. For example,
The mesa 522 presents a surface of the cap 521 opposite the surface 101A of beam 101, and defines the gap 525 between the beam 101 and cap 521. In some embodiments, the surface 522A presented by mesa 522 to the beam surface 101A may be same size and shape as the beam surface 101A. In other embodiments, the surface 522A presented by mesa 522 to the beam surface 101A may be larger than, or smaller than, the beam surface 101A. However, if the surface area of surface 522A is made too small, then the damping effects of the gap 525 may be lost. The appropriate surface area of surface 522A may be determined based on the amount of desired damping.
In some embodiments, a mesa (e.g., 681) may include several mesa portions 682 which together act as a single mesa to define the surface area, and gap between mesa and beam (101). Two examples are illustrated in
Another embodiment of an accelerometer 540 is schematically illustrated in
Yet another embodiment if an accelerometer 560 is schematically illustrated in
Although accelerometers 520 and 560 each schematically illustrate a mesa on their respective caps, other embodiments may include a mesa on a substrate, and some embodiments includes a mesa on both the cap and substrate.
To address the risk of stiction, some embodiments may optionally include an anti-stiction coating, or one or more standoffs, such as standoff 610, as schematically illustrated in
Although standoff 130 is shown as extending from the inner surface 111 of cover 110, a standoff could be included on any surface that presents a risk of stiction, as schematically illustrated by standoffs 611 on substrate 102, for example. Some embodiments, such as accelerometer 650 schematically illustrated in
Although illustrated as individual caps in the embodiments above, in some embodiments, the accelerometer may be a portion of a device wafer, and the cap (e.g., caps or covers 521, 541, 561, 110, 653, for example) may be a portion of a cap wafer. Indeed, in some embodiments, the cap wafer may be an ASIC or other integrated circuit wafer, such that each cap portion of the cap wafer may be a “smart cap,” which includes at least one of integrated circuitry (e.g., active devices such as transistors), electrical conduits, or terminals, etc. In various embodiments, the cap wafer may optionally include mesa portions, standoffs, or both.
An embodiment of a method 700 of fabricating an accelerometer is presented in
The cap is fabricated in n step 702. One advantage of various embodiment is that some caps, such as cap 110 for example, may be fabricated without the need for deep silicon etching, and therefore may avoid the need to employ an expensive silicon deep etch tool. In other words, using cap 110 as an example, because the inner surface 110A of cap 110 does not need to be as far from the beam as in prior art accelerometers (such as accelerometer 200 for example), the cap does not need to be as deeply etched. Rather, the shallow cavity 110B in cap 110 can be formed by controlled shallow silicon etch, for example on a cap wafer. Alternately, in some embodiments, such as accelerometer 500 for example, etching a cavity in the cap or cap wafer can be avoided entirely, and the gap 505 can be controlled by controlling the thickness of the intermediate layer 502.
In addition, these techniques provide a thinner accelerometer and reduce the die package vertical profile, as compared to prior art accelerometers, such as accelerometer 200 for example.
At step 703, the substrate, beam and cap or cap wafer are surrounded by a gas, such as a low viscosity gas. However, in some embodiments, even high viscosity gasses may be used, for example if very high damping is desired.
Then, at step 704, the cap, or cap wafer, is hermetically sealed to the substrate, or substrate wafer.
Optionally, if the substrate is a substrate wafer and the cap is a cap wafer, the bonded wafers may be diced (705) to yield a number of individual capped, damped accelerometers.
Although the accelerometer schematically illustrated and discussed above are capacitance-type accelerometers, other accelerometers measure the displacement of the beam in other ways. For example, some accelerometers measure the displacement of a beam by use of piezo elements in the suspension system. However, for ease of illustration, examples of capacitive MEMS accelerometers are discussed herein, with the understanding that the principles disclosed are not limited to capacitance-based accelerometers, and could be applied to other accelerometer, including piezo-based accelerometers for example.
The embodiments of the invention described above are intended to be merely exemplary; numerous variations and modifications will be apparent to those skilled in the art. All such variations and modifications are intended to be within the scope of the present invention as defined in any appended claims.