1. Field of the Invention
The present invention relates to a capacitive sensor for measuring distance, in particular capacitive sensor for measuring distance to a target in a lithography apparatus.
2. Description of the Related Art
In many applications it is important to measure an electrical current very precisely. For example, charged particle and optical lithography machines and inspection machines for example, typically require highly accurate measurement of the distance from the final lens element of the machine to the surface of a wafer or other target to be exposed or inspected. These machines and others with movable parts often require precise alignment of various parts which may be achieved by measuring distance from the moveable part to a reference point. Capacitive sensors may be used in such applications requiring fine position or distance measurement. When a capacitive sensor is energized, an electrical current flows through the sensor which varies in dependence on the distance between the sensor element and an opposing surface. A precise measurement of this current may be used to accurately determine the measured distance.
To measure an electric current, a measurement circuit may be used having the current to be measured as the input and providing a measurement signal as an output, often in the form of a voltage which may be further processed and converted to a digital signal. There are several factors which contribute to errors in such measurement circuits. These include stray impedance in the input circuitry of the measuring circuit, a limited common mode rejection ratio (CMRR) of the input circuitry, and inaccuracy on the transfer function of the measurement circuit independent of common mode. The value of such stray impedance may change, e.g. depending on factors such as temperature, and disturbances on the input may also change with time. This makes it difficult to compensate for these effects.
It is often necessary to locate the electronic measurement circuits used for driving the capacitive sensors and for generating the desired measurement signals at a distance from the sensors due to the inhospitable environment in which the sensors are located or lack of a suitable place to locate the circuits close to the sensors. In modern lithography applications such as EUV and charged particle systems, the sensors are typically located in a vacuum environment that is very sensitive to contaminants and outside disturbances, and which creates problems with heat removal from electronic circuits if they are located in the vacuum environment, and impedes access for maintenance for such circuits.
The wiring connections between the sensors and remotely located driving and measurement circuits introduce parasitic capacitances into the system which affect the reading of the sensor. If the measuring circuits could be located at the sensor probe, the sensor current could be measured directly and accurately. Because of these parallel parasitic capacitances introduced by the cabling system, measurement of current flow in the sensor is often avoided in systems with remotely located measuring circuits. Conventional solutions introduce measurement errors which need to be taken into account, usually by calibrating the combined sensor and wiring installation. The longer the wiring connection, the more severe these problems become.
The requirement to calibrate the sensors in combination with the sensor wiring reduces flexibility in designing and building sensor systems and increases their cost, and it adds a requirement for recalibration whenever a sensor or its wiring is replaced, making such a replacement complex, time-consuming, and expensive.
The invention seeks to solve or reduce the above drawbacks to provide an improved measurement system for measuring an input electrical current from a current source and generating a current measurement signal, comprising a current measuring circuit having a first input terminal connected to the current source and an output terminal for providing the current measurement signal. The current measuring circuit further comprises one or more power supply terminals arranged to receive one or more voltages from a power supply for powering the current measuring circuit. The current measuring circuit also comprises a first voltage source coupled to the one or more power supply terminals, the first voltage source providing a disturbance voltage to the one or more power supply terminals, the disturbance voltage representing a voltage at the first input terminal.
The measurement system may further comprise a difference circuit arranged to subtract a voltage generated by the first voltage source from a signal at the output terminal of the current measuring circuit to generate the current measurement signal.
The first voltage source may be connected to the first input terminal of the current measuring circuit for driving a load to form the current source. The load may comprise a capacitive sensor for generating a current which varies in dependence on distance between the capacitive sensor and a target. The load may be connected to the first input terminal of the current measuring circuit by a cable comprising a sensor wire and a shield conductor, wherein the sensor wire is connected in series between the load and the first input terminal and the shield conductor is connected to the first voltage source.
An output terminal of the first voltage source may be coupled via one or more capacitors to the one or more power supply terminals of the current measuring circuit. The current measuring circuit may comprise a current-to-voltage converter.
The current measuring circuit may comprise an operational amplifier, a negative input terminal of the operational amplifier serving as the first input terminal of the current measuring circuit and an output terminal of the operational amplifier serving as the output terminal of the current measuring circuit, the operational amplifier further comprising a positive input terminal and one or more power supply terminals, wherein the positive input terminal of the operational amplifier is electrically connected to the one or more power supply terminals of the operational amplifier. The positive input terminal of the operational amplifier may be electrically connected to the one or more power supply terminals of the operational amplifier via one or more capacitors.
The first voltage source may be used to generate a voltage with a triangular waveform, and the current source may generate a current with a substantially square waveform.
In another aspect, the invention relates to a method for measuring an input electrical current from a current source and generating a current measurement signal. The method comprises the steps of providing the input current to a first input terminal of a current measuring circuit, the measuring circuit having one or more power supply terminals arranged to receive one or more voltages from a power supply for powering the current measuring circuit, providing a disturbance voltage to the one or more power supply terminals, the disturbance voltage representing a voltage at the first input terminal, and generating an output signal at an output terminal of the current measuring circuit representing the input electrical current at the first input terminal of the current measuring circuit.
The method may further comprise subtracting the disturbance voltage from the output signal at the output terminal of the current measuring circuit to generate the current measurement signal. The method may also comprise driving a load with a voltage to generate the input electrical current at the first input terminal of the current measuring circuit, and the load may comprise a capacitive sensor for generating a current which varies in dependence on distance between the capacitive sensor and a target.
The method may further comprise connecting the load to the first input terminal of the current measuring circuit by a cable comprising a sensor wire and a shield conductor, wherein the sensor wire is connected in series between the load and the first input terminal and the shield conductor is energized with substantially the same voltage used to drive the load.
The disturbance voltage may be provided to the one or more power supply terminals via one or more capacitors, and may be isolated from the power supply voltages by one or more inductors.
Various aspects of the invention will be further explained with reference to embodiments shown in the drawings wherein:
The following is a description of various embodiments of the invention, given by way of example only and with reference to the drawings.
A capacitive sensor uses a homogeneous electric field set up between two conductive surfaces. Over short distances, the applied voltage is proportional to the distance between the surfaces. Single-plate sensors measure the distance between a single sensor plate and an electrically conductive target surface.
The capacitive sensor may be energized by an AC voltage source or AC current source, and the resulting voltage across the sensor or current through the sensor is measured. The measurement signal generated is dependent on the sensor-to-target capacitance of the sensor. The system can be calibrated to the measurement capacitor and to measure the current/voltage.
The environment in which capacitive sensors are typically applied in industrial applications is often an unsuitable location for the current or voltage source for driving the capacitive sensors and the measurement circuits for processing signals from the sensors. As a result, the driving source and measurement circuits are typically located remotely from the sensors, requiring a cable connection to the sensor. A cabling connection between the sensors and the remote circuits will introduce additional undesirable capacitances in the system, even when the cable is short.
A voltage source 20 is connected through a current measurement circuit 21 to one end of the sensor wire 31 and the measurement electrode of the capacitive sensor is connected to the other end of the sensor wire. The voltage source 20 supplies an AC voltage to energize the capacitive sensor 1, and the current measurement circuit 21 measures the current flowing in the sensor wire 31 through the capacitive sensor 1. The current flowing through the sensor wire 31 varies in dependence on the sensor capacitance 4, which varies in dependence on the distance being measured by the sensor.
The current flowing in the sensor wire 31 will include a component due to current flowing through the sensor capacitance 4 and also a component due to current flowing through the cable capacitance 36. The cable capacitance 36 should be small in comparison to the sensor capacitance 4 because large stray capacitances increase the proportion of current flowing through the stray capacitances in comparison to the current flowing through the sensor capacitance desired to be measured, and reduces the sensitivity of the measurement. However, the cable capacitance is typically large and has an adverse effect on sensor system sensitivity.
Active guarding may be used to minimize the effect of the cable capacitance.
Current flow through stray cable-to-ground capacitance 37 is supplied by shield driver 24. The input current to shield driver 24 will contribute to the current measured by current measurement circuit 21 resulting in error, but the shield driver has a high input impedance and its input current is relatively small so that the resulting error is small. However, for long cables and higher measurement frequencies this arrangement is difficult to realize. The shield driver also has some input capacitance, which will draw additional current. The measured capacitance is the sum of the sensor capacitance 4 and these additional error capacitances; the deviation from unit gain of the shield driver 24 multiplied by the stray capacitance 36, and the input capacitance of the shield driver 24.
The measurement error can be reduced by rearranging the circuit as shown in
The output of voltage source 20a is connected to the input of shield driver 24a, the output of shield driver 24a is connected to one terminal of current measurement circuit 21a, and the other terminal of measurement circuit 21a is connected to sensor wire 31a. The same arrangement is used for voltage source 20b, shield driver 24b, current measurement circuit 21b, and sensor wire 31b. The Voltage sources 20a and 20b generate AC voltage waveforms phase offset by 180 degrees to each other. The target conducts the alternating current between the two sensors 1a and 1b through the two sensor capacitances 4a and 4b. The target behaves like a virtual ground for the two measurement systems; this is optimal if the sensor capacitances 4a and 4b are equal. The potential of the target will be removed as a common mode disturbance when the difference between the two current measurements 22a and 22b is calculated.
Moving the input of the shield driver to a point ‘before’ the current measurement omits the input capacitance of the shield driver from the capacitance measurement, thus eliminating this component of error from the measurement. This can also be viewed as a feed forward of the shield driver output to the shield conductor. The voltage source output is still transferred to the sensor wire, and is also directly connected to drive the shield conductor, instead of buffering the sensor wire voltage in order to load the shield conductor. Connecting the shield driver in series between the voltage source and measurement circuit has the additional benefit of removing error caused by deviation from unity gain of shield driver, because the shield driver output is connected to both the sensor wire (through the measurement circuit) and the shield conductor.
The arrangement of
Current through the capacitance 37 between the shield 32 and ground is supplied from the voltage source 20 or separate shield driver 24, and this current does not form part of the measured current and has only a second order effect on the voltage at the output of the voltage source. Any deviation from unity gain of the shield driver and the effect of input capacitance of the shield driver are both eliminated in this arrangement.
In effect the arrangement in
A grounded outer shield conductor may also be added to the configurations of
Conventional capacitive sensing systems often drive the sensors using a current source and measure the resulting voltage across the sensor capacitance. The invention, e.g. in the configurations shown in
The shield driver may be implemented as an op-amp, preferably with low output impedance. The shield driver may be integrated into the voltage source for driving both the sensor wire and the shield conductor as described above.
An example of a triangular voltage source waveform is shown in
The capacitive sensor may be a conventional capacitive sensor or a thin film structure as described in U.S. patent application Ser. No. 12/977,240, which is hereby incorporated by reference in its entirety.
Many alternatives to the above arrangements are possible. For example, a coaxial, triaxial, or cable with four or more conductors may be used. A cable with one or more shield conductors in a non-coaxial arrangement may also be used, e.g. with the conductors arranged in a flat configuration with a central sensor wire with shield conductors on either side. The shield driver may be separate from or integrated in the voltage source. A single voltage source may be used to drive multiple sensors. This is particularly advantageous in the configurations with the shield driver integrated with the voltage source, greatly reducing the number of separate components used in the sensor system.
Some example calculations may be used to illustrate the improvement in the performance of the invention. For a sensor with a 4 mm sensing surface diameter at a nominal measuring distance of 0.1 mm results in a nominal sensor capacitance of approximately 1 pF. A cable of type RG178 and length five meters results in a cable capacitance between core and shield conductors of approximately 500 pF. A shield driver amplifier with a gain bandwidth factor of 100 MHz and measurement frequency of 1 MHz results in a gain of 0.99, i.e. with a deviation of 0.01 from unity gain. Using these example values, the steady-state performance of the configurations described above can be estimated. A conventional active shielding configuration as shown in
The performance of the configurations described above can also be estimated when an external disturbance causes a change in current in the shield conductor. For example, assuming a change in current in the shield conductor causes an additional 1% gain error in the shield driver, the conventional active shielding configuration as shown in
In the embodiment shown in
In the embodiment shown in
The capacitive sensors used in any of the applications shown in
These sets of sensors may be arranged in sets of six sensors to from three differential sensor pairs, for measurement in three axes, i.e. horizontal X, Y-axes and vertical Z-axis directions. This may be accomplished by mounting the differential sensor pairs oriented for measuring distance to each direction to a suitable opposing surface. Measurement signals from the sensors may be sued to adjust the position of moveable parts of the lithography machine, e.g. using a piezomotor to make small movements to obtain proper alignment of the part within the system.
Each set of sensors is connected via a cable 30 to a corresponding current measurement circuit located in a cabinet outside the vacuum chamber and remote from the lithography machine.
The current measurement circuits 21, 21a, 21b may be implemented, for example, as a current-to-voltage converter or a current-to-current converter. There are several factors which contribute to errors in such measurement circuits. These include stray impedance in the input circuitry of the measuring circuit, a limited common mode rejection ratio (CMRR) of the input circuitry, and inaccuracy on the transfer function of the measurement circuit independent of common mode.
These measurement errors can be reduced by driving the supply voltages with the same voltage present at the input terminal of the measurement circuit. In this way, the disturbances on the input are transferred to the supply voltages to reduce or eliminate currents flowing in the measuring circuit caused by varying voltage differences between the input signal and internal circuits in the measuring circuit.
The voltage supply terminals 75 and 76 of the current measuring circuit are connected to a power supply comprising voltage sources 77a, 77b. A voltage source VD is provided to feed voltage disturbances at the input terminal into the power supply, to that voltage differences between the input signal and the measuring circuit supply voltages remain constant. The voltage source VD is connected to the measuring circuit power supply, so that the power supply voltages are also driven by any voltages present at the input terminal of the measuring circuit. The voltage source VD may be provided by suitable feedback or feed forward in the circuit.
In the embodiment shown in
The embodiment in
The current source CS produces a current Ics to be measured. An impedance 87 connected between the input terminal 82 and the output terminal 84 provides negative feedback, and the opamp 80 operates to maintain the voltage difference between the two input terminals 82 and 83 at nearly zero. The opamp 80 has a very high input impedance so that very little of the current Ics flows into the opamp, but instead flows through impedance 87. However, due to stray impedances in the input circuitry of the opamp 80 and a limited CMRR of the opamp, the opamp 80 cannot completely eliminate the influences of common mode voltages on the inputs.
In the embodiment shown, an AC voltage supply VG is used to drive the input terminal 83. Because the opamp 80 is configured to maintain the two input terminals 82 and 83 at almost the same voltage, the voltage VD effectively represents a common mode disturbance on the input terminals. The output of the voltage source VD, connected to the input terminal 83, is also connected to the opamp power supply circuit to feedforward the common mode disturbance voltages into the power supply voltages of the opamp 80. In this embodiment, the output of the voltage source VD is connected via capacitors 93, 94 to couple the voltage at input terminal 83 to the voltage supply to power supply terminals 85, 86. In this way, DC voltage sources 91, 92 supply a DC voltage to power supply terminals 85, 86 while AC voltages present at input terminal 83 are also supplied to the power supply terminals 85, 86. Inductors 95, 96 may also be included in the power supply as shown in the embodiment in
The voltage source 20 energizes the shield conductor 32 at the remote end of the cable 30 to energize the guard electrode 42. The voltage source 20 also energizes the sensor wire 31 via the opamp 80 to energize the sensing electrode 41 of the capacitive sensor. Because the opamp maintains the voltages at its input terminals 82, 83 at essentially the same voltage, the sensor wire 31 and shield conductor 32 are also energized at essentially the same voltage, virtually eliminating capacitive leakage current between them.
The output terminal of the voltage source 20 is connected to input terminal 83, the shield conductor 32, and is also connected to the power supply for the opamp 80 as described earlier, and is connected to a difference circuit 88 to subtract the signal from the voltage source 20 from the output signal of the opamp 80.
The voltage source preferably provides a triangular voltage signal to drive the capacitive sensor, as described earlier. This results (ideally) in a square-wave current signal shown in
A frequency reference FSYNC is generated (e.g. at 2 MHz) and divided in divider circuit 51 to generate multiple separate square-wave signals at a lower frequency with certain predetermined phase offsets. In this embodiment, four separate 500 kHz square-wave signals are generated with 90 degree phase offsets.
Integrator circuit 52 generates a triangular voltage waveform from one of the square-wave signals, and from this the amplifier circuits 53a and 53b generate two triangular voltage waveforms 180 degrees out-of-phase. For example, these two out-of-phase triangular voltage waveforms may correspond to the outputs of voltage sources (e.g. 20, 20a, 20b, VD) shown in any of
The current-to-voltage converters 54a and 54b generate voltage signals at their outputs representing a measurement of the current signals at their inputs (i.e. the output signals 22, 22a, 22b, 74, 84 of
Selectors 56a, 56b use one or more of the phase shifted reference signals generated by divider circuit 51, e.g. 180 and 270 degree shifted reference signals shown in
When the circuit is used with a sensor pair operated in differential mode, the sampling may be performed to switch between the two measured current signals, to accumulate the positive amplitudes in one signal (
Example waveforms at the output of amplifiers 58a, 58b are shown in
The invention has been described by reference to certain embodiments discussed above. It should be noted various constructions and alternatives have been described, which may be used with any of the embodiments described herein, as would be known to those of skill in the art. In particular, the current measuring circuits described in relation to
This is a reissue of U.S. Pat. No. 9,644,995, issued on May 9, 2017, from U.S. patent application Ser. No. 13/539,585, which claims the benefit of priority from U.S. patent application Ser. No. 61/503,555, filed Jun. 30, 2011. The entire contents of U.S. patent application Ser. No. 13/539,585 are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
3101024 | Huebner | Aug 1963 | A |
3713022 | McRay | Jan 1973 | A |
4538069 | Shambroom et al. | Aug 1985 | A |
5489888 | Jagiella | Feb 1996 | A |
5730165 | Philipp | Mar 1998 | A |
5963023 | Herrell | Oct 1999 | A |
6014030 | Smith | Jan 2000 | A |
6255842 | Hashimoto | Jul 2001 | B1 |
6411119 | Feldtkeller | Jun 2002 | B1 |
6486681 | Weber et al. | Nov 2002 | B1 |
6791314 | Bortolussi | Sep 2004 | B1 |
7088112 | Yakabe | Aug 2006 | B2 |
7138808 | Wakamatsu | Nov 2006 | B2 |
20040075442 | Iannello | Apr 2004 | A1 |
20040191935 | Tinnemans | Sep 2004 | A1 |
20050002004 | Kolesnychenko | Jan 2005 | A1 |
20090167315 | Lindsey | Jul 2009 | A1 |
20090237068 | Vora | Sep 2009 | A1 |
20090246703 | Starreveld et al. | Oct 2009 | A1 |
20090295366 | Cehelnik | Dec 2009 | A1 |
20100283539 | Yanagisawa | Nov 2010 | A1 |
20110193573 | De Boer | Aug 2011 | A1 |
20110193574 | De Boer et al. | Aug 2011 | A1 |
Number | Date | Country |
---|---|---|
1890880 | Jan 2004 | CN |
1890880 | Jan 2004 | CN |
1846116 | Oct 2006 | CN |
101341398 | Jan 2009 | CN |
101341398 | Jan 2009 | CN |
101490642 | Jul 2009 | CN |
101490642 | Jul 2009 | CN |
101762736 | Jun 2010 | CN |
101762736 | Jun 2010 | CN |
1 602 892 | Dec 2005 | EP |
1 602 892 | Dec 2005 | EP |
S 5728266 | Feb 1982 | JP |
S5728266 | Feb 1982 | JP |
2000-504110 | Apr 2000 | JP |
2000-504110 | Apr 2000 | JP |
2006-006007 | Jan 2006 | JP |
2010-286347 | Dec 2010 | JP |
2011-053201 | Mar 2011 | JP |
2011-053201 | Mar 2011 | JP |
1160321 | Jun 1985 | RU |
1160321 SU | Jun 1985 | RU |
WO 2005 003688 | Jan 2005 | WO |
WO 2005 003688 | Jan 2005 | WO |
WO 2005 036608 | Apr 2005 | WO |
WO 2005 036608 | Apr 2005 | WO |
WO 2007 072069 | Jun 2007 | WO |
WO 2007 072069 | Jun 2007 | WO |
WO 2008 009687 | Jan 2008 | WO |
WO 2008 009687 | Jan 2008 | WO |
Entry |
---|
Ferran Reverter et al. “Stability and accuracy of active shielding for grounded capacitive sensors”, Institute of Physics, Meas. Sci. & Tech. Sep. 28, 2006, pp. 2884-2890. |
Number | Date | Country | |
---|---|---|---|
61503555 | Jun 2011 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 13539585 | Jul 2012 | US |
Child | 16408309 | US |