The circuitry of a capacitive nanometer displacement sensor using the ring oscillator has been analyzed and characterized. We focus on the sensitivity of the sensor to detect the nanometer displacement or strain. The displaced target object must be conductive and the medium around the target object must be an insulator or a vacuum. The sensitivity in the range of L < 1 μm is enhanced with decreases in the size of the sensor electrode, and using a higher free-running oscillation frequency can increase sensitivity. The proposed sensor, which converts the displacement of the target object to the oscillation frequency, was fabricated with CMOS 350 nm technology, and the sensitivity was estimated at 8.16 kHz/nm. The results of our study indicated that the presented sensor has enough sensitivity to detect the nanometer displacement of the target object at a distance within 1 μm from the surface of the sensor electrode.
1. Introduction
Proximity sensors and tactile sensors working in the very narrow nominal range can be used to detect microparticles and micromotion of the objects. Furthermore, the integrated proximity sensors have a wide range of applications, such as measurement of the texture, analysis of fingerprints [1], measurement of the tactile or strain distribution [2], and use in touch screens [3]. The proximity sensors and the sensitive displacement sensors in previous studies have been implemented on the basis of various principles of measurement, for example, a capacitive coupling method and some variations with a 30 nm resolution [4, 5], an Eddy current method [6], a millimeter-wave reflection method with a 10 μm resolution of [7], and an integrated Michelson interferometry with a 20 nm resolution [8]. In particular, the capacitive proximity sensors based on an RC oscillation [9] and a delta-sigma modulation [10] offer technical advantages, that is, a higher sensitivity and higher sampling speed because of the higher operating frequency of the electronic circuit as the semiconductor technology is scaled down. The capacitive sensor based on the RC oscillation can be implemented in a very small area, and it is possible to be implanted in the structural element of buildings, machines, and living organisms.
In this paper, we present the circuit analysis of a nanometer displacement sensor, that is, a very high sensitive capacitive proximity sensor, and characterization results of the proposed sensor chip. We focus on the sensitivity of the sensor to detect displacement or strain at the nanometer scale.
2. Circuitry and Sensitivity Analysis
A cross-sectional view of the sensor chip is shown in Figure 1. The top metal is dedicated to the ground electrode and the sensor electrode. The target object forms capacitances Cg and Cs against the sensor electrode and ground electrode. The Cf is a parasitic capacitance between the two electrodes. The capacitances Cg and Cs depend on the distance between each electrode and target object while the capacitance Cf is determined by the geometry of the ground and sensor electrodes. On the assumption that the conductive object has a flat surface, the total capacitance CA between the electrodes is shown in:CA(L)=1(1/Cg(L))+(1/Cs(L))+Cf=Cs(L)n+1+Cf≅εrε0S(n+1)L+Cf,n=Cs(L)Cg(L),
where n is a ratio of Cs and Cg, L is a distance between the bottom of the target object and top surface of the ground or sensor electrodes, S is an area of the sensor electrode, and εr and ε0 are a relative permittivity of the ambient and an electric constant, respectively. If a round-headed tip with the curvature radius R is used as a target object, CA is replaced by CAR shown in (1c), given that the conductive object is grounded and R is sufficiently smaller than the sensor electrode: CAR(L)=4πεrε0R1-(R/2(L+R))+Cf.
Cross-section of sensor chip.
A schematic diagram of the circuit detecting a capacitance change of CA is shown in Figure 2. The sensing ring oscillator is connected to the sensor electrode, and the oscillation frequency fS changes depending on the value of the capacitance CA. On the other hand, the reference ring oscillator is connected to the reference capacitance CR. The oscillation frequency fR of the reference ring oscillator is fixed by the capacitance CR. These ring oscillators are adjacently placed each other with a matching layout technique to cancel the difference of electronic characteristics of the transistors. It is difficult to count the oscillation frequency of the ring oscillators because the oscillation frequency of the ring oscillator is very high. The output signals from two oscillators are mixed with each other, and the output frequency of the mixer circuit is converted to |fS±fR|. The RC low-pass filter (LPF) passes the down-converted signal at|fS-fR|,selectively. The frequency of the down-converted signal is counted by the 28-bit counter. The counting period is controlled by the pulse width of the “Enable” signal, and the bit width of the output value depends on the period of the enable signal. The precision of the frequency measurement is thus inversely proportional to the sampling frequency of the counter output.
Schematic diagram of capacitive sensor with two ring oscillators.
The free-running frequency fosc of the 3-stage ring oscillator is determined by the parasitic capacitance CL in each inverter, transconductance parameter β of MOSFETs (metal-oxide-semiconductor field effect transistor), and power supply voltage VDD according to the following equations [11]: fosc=16td0,td0=3.7CLβVDD,where value td0 is the delay time of the inverters. The extra load capacitance CA is then added to the sensing ring oscillator, and the frequency fS of the sensing ring oscillator is estimated as follows: fS=16td0+2Δtd,Δtd=3.7CAβVDD=td0CACL.
From (1a), (2a), and (3), Equation (4) is derived: fS=12td0(3+(CA/CL))=3fosc3+(CA/CL).
The sensitivity of the sensor for the displacement of the target object Kd is found by using (4): Kd=dfSdL=dfSdCAdCAdL=3foscCL/CA(L)(3+(CA(L)/CL))21L.
The parameters fosc and CL depend on the fabrication technology, and CA is a function of the distance L. The free-running oscillation frequency fosc and the sensitivity of the sensor increase with the advancement of technology node. By using (5) with the assumption that n=1, εr=1 (in vacuum), the sensitivity of the sensor at distance L was estimated by using the typical values of fosc~55 GHz and CL~0.3 fF in the CMOS (complementary metal-oxide-semiconductor) 32 nm technology [12]. The L dependence of sensitivity for the size of the sensor electrode is shown in Figure 3.
Sensitivity for displacement at L. The curves are calculated assuming CMOS 32 nm technology.
The sensitivity in the range of L<1μm is enhanced by using a smaller sensor electrode. On the other hand, the sensitivity in the range of L>1μm decreases with smaller sensor electrode. The displacement of the target in the nanometer scale is detected as a change of the oscillation frequency in the MHz band.
For a round-headed object, the sensitivity for the displacement of the target object is derived based on (1c):Kd=3foscCL/CAR(L)(3+(CAR(L)/CL))21(L+R)(2L+R)/R.
The L dependence of sensitivity for the round-headed object is similar to the calculation result shown in Figure 3, and the sensitivity is increased with the smaller curvature radius of the object. However, the maximum sensitivity becomes 10 times lower than that for an object which has a flat surface.
3. Results
The sensor circuit presented in Figure 2 was fabricated by using CMOS 350 nm technology. The chip photograph is shown in Figure 4. This chip includes three discrete sensors and an array of 120 sensors. The discrete sensors were used to characterize the shift of the oscillation frequency, and the sensor in the center of the array was used to observe the counter output. With the exception of the active one at the center, all sensor electrodes were connected to the ground by the control signal to switch between the sensor circuit and the ground. The size of the sensor electrode was 39 μm × 39 μm, and the space between the active sensor electrode and the grounded electrode was 10 μm. The size and space of the sensor electrode was not optimized for high sensitivity, but the sensitivity of the sensor with larger electrodes was less affected by the process variation of the chip.
Chip photograph of nano-displacement sensor. Die is 2.4 mm × 2.4 mm, and sensor electrode is 39 μm × 39 μm.
The spectra of the output signal of the sensing ring oscillator are shown in Figure 5. A round-headed tungsten probe with a 60 μm curvature radius was employed as a target object. The capacitance between the tungsten probe and the sensor electrode can be approximated by using the parallel-plates model shown as (1a) because the curvature radius of the target object is larger than the sensor electrode. The oscillation frequencies fS for L=10μm and 1 μm were 266.6225 MHz and 348.2000 MHz, respectively. The sensitivity is estimated at 8.16 kHz/nm. Higher sensitivity is expected in the range of L<1μm, but the passivation film on the chip obstructed the measurement. The curve of oscillation frequency versus distance will be shown elsewhere after a reattempt to control distance by using an improved chip and an accurate mechanism. The value of the sensitivity is equivalent to that where a 1 nm displacement is measured with precision of 8 bit within 31 ms if there is no phase noise and no fluctuation of the oscillation frequency. The ring oscillator does not have good noise performance. However, the deterioration of the measurement accuracy caused by the influence of the noise can be controlled by the frequency count of the long period. The output value of the counter versus time is shown in Figure 6. The output period is 12.8 μs. These responses are observed with no target object on the sensor chip and in the condition that the surface mount device of the EIA 0603 standard is placed on the sensor surface, respectively. The output value at 1 s implies the frequency of the down-converted signal. The weak nonlinearity of the counter output-time characteristics was observed at 90 ms after the start of measurement. This nonlinearity could be regarded as a result of the temperature drift of the ring oscillator by self-heating.
Spectra of sensing ring oscillator. (a) Distance from target object was (a) 1 μm and (b) 10 μm. Target object was round-headed tungsten probe with curvature radius of 60 μm.
Output value of counter versus time. Output period is 12.8 μs. Output value at 1 s implies the frequency of down-converted signal.
4. Conclusions
The circuitry of capacitive nanometer displacement sensor using the ring oscillator has been characterized. The sensitivity in the range of L<1μm is enhanced with decreases in the size of the sensor electrode, and using a higher free-running oscillation frequency increases sensitivity. The proposed sensor was fabricated using CMOS 350 nm technology, and the sensitivity was estimated at 8.16 kHz/nm. It has been shown that the presented sensor has enough sensitivity to detect the nanometer displacement of the target object that is within 1 μm from the surface of the sensor electrode.
Acknowledgments
This work is supported by VLSI Design and Education Center (VDEC), The University of Tokyo in collaboration with Cadence Corporation and Mentor Graphics, Inc. The VLSI chip in this study has been fabricated in the chip fabrication program of VDEC, the University of Tokyo in collaboration with Rohm Corporation and Toppan Printing Corporation. This work was also supported by Grant-in-Aid for Scientific Research (C) (20510116) of Japan Society for the Promotion of Science and Adaptable & Seamless Technology Transfer Program through Target-driven R&D (AS2121327A) of Japan Science and Technology Agency.
HashidoR.SuzukiA.IwataA.OkamotoT.SatohY.InoueM.A capacitive fingerprint sensor chip using low-temperature poly-Si TFTs on a glass substrate and a novel and unique sensing method20033822742802-s2.0-003731951010.1109/JSSC.2002.807172GoegerD.dirk.goeger@kit.eduBlankertzM.matthias.blankertz@student.kit.eduWoernH.woern@kit.eduA tactile proximity sensorIEEE Sensors2010Kona, Hawaii, USA58959410.1109/ICSENS.2010.5690450HanJ. Y.Low-cost multi-touch sensing through frustrated total internal reflectionProceedings of the 18th Annual ACM Symposium on User Interface Software and Technology (UIST '05)October 20051151182-s2.0-33745857568YangH.LiR.WeiQ.LiuJ.The study of high accuracy capacitive displacement sensor used in non-contact precision displacement measurementProceedings of the 9th International Conference on Electronic Measurement and Instruments (ICEMI '09)August 20091641682-s2.0-7154912684210.1109/ICEMI.2009.5274784BaxterL. K.1996New York, NY, USAJohn Wiley & SonsKoibuchiK.SawaK.HonmaT.HayashiT.UedaK.SasakiH.Eddy-current type proximity sensor with closed magnetic circuit geometry2007434174917522-s2.0-3394764539010.1109/TMAG.2007.892509KimS.NguyenC.On the development of a multifunction millimeter-wave sensor for displacement sensing and low-velocity measurement20045211250325122-s2.0-924424361810.1109/TMTT.2004.837153HofstetterD.ZappeH. P.DändlikerR.Optical displacement measurement with GaAs/AlGaAs-based monolithically integrated Michelson interferometers19971546636702-s2.0-0031119356GasullaM.LiX.MeijerG. C. M.The noise performance of a high-speed capacitive-sensor interface based on a relaxation oscillator and a fast counter2005545193419402-s2.0-2764444273710.1109/TIM.2005.853684BingesserM.LoeligerT.HinnW.HauerJ.MödlS.DornR.VölkerM.Low-noise sigma-delta capacitance-to-digital converter for sub-pF capacitive sensors with integrated dielectric loss measurementDesign, Automation and Test in Europe (DATE '08)March 20088688722-s2.0-4974910854510.1109/DATE.2008.4484783HodgesD. A.JacksonH. G.1983New York, NY, USAMcGraw-HillThe International Technology Roadmap for SemiconductorProcess Integration, Devices, and Structures, Sec. Logic Technology Requirements, pp.6–9, 2009, http://www.itrs.net/reports.html