Ultra sensitive silicon sensor millimeter wave passive imager

Information

  • Patent Application
  • 20050087687
  • Publication Number
    20050087687
  • Date Filed
    October 22, 2003
    21 years ago
  • Date Published
    April 28, 2005
    19 years ago
Abstract
Electro-thermal feedback is utilized for zeroing the thermal conductance between a bolometer type detector element of a pixel in a thermal radiation sensor assembly and the environments through its mechanical support structure and electrical interconnects, thereby limiting the thermal conductance primarily through photon radiation. Zeroing of the thermal conductance associated with the mechanical support and electrical readout interconnect structures is achieved by electro-thermal feedback that adjust the temperature of an intermediate stage by the heating effect of a bipolar transistor amplifier circuit so that the temperature across the mechanical support and electrical interconnects structures are zeroed thereby greatly improving the thermal isolation, the responsivity and sensitivity of the electromagnetic radiation sensor.
Description
BACKGROUND OF THE INVENTION

1. Field of the Invention


This invention relates generally to bolometer type sensors for detecting thermal radiation and more particularly to ultra sensitive silicon bolometer type sensors usable for passive or active imaging at millimeter (MM) wavelengths.


2. Description of Related Art


Infrared (IR) bolometers are used and proposed for use in many new applications. The principal application is construction of thermal cameras. Interest in bolometers stems from the fact that their performance has significantly improved, they're sensitive at much longer wavelengths, and offer higher operating temperatures. Specifically, IR cameras, with large bolometer arrays have achieved a sensitivity, a Noise Equivalent Temperature resolution (NEΔT) better than ≈0.1K. Such performance is less than that of quantum detectors, however, for many applications it is adequate and cost effective. Improved bolometer performance is achieved primarily through improved thermal isolation, made possible with advances in IC micro-machining technology. The thermal isolation achieved is about an order of magnitude from radiation limited isolation.


Bolometers inherently operate at slower rates than quantum detectors. However, with staring focal plane arrays, the slow speed limitation is alleviated, since the pixel integration times correspond to the frame rate, and is much longer than line times in scanning systems. Thus the main obstacle to making bolometers more sensitive are practical limitations in thermally isolating each pixel element. With improved thermal isolation, the bolometers performance will directly improve and thereby find wider applications, including potential replacement for cryogenic FLIR cameras. With ideal thermal isolation, the anticipated NEΔT improvement is about an order of magnitude in sensitivity.


LWIR and MWIR silicon bolometers having a new operating mode are disclosed in U.S. Pat. No. 6,489,615 entitled “Ultra Sensitive Silicon Sensor”, issued to Nathan Bluzer, the present inventor, on Dec. 3, 2002. This patent is assigned to the present assignee and is incorporated herein by reference in its entirely.


In U.S. Pat. No. 6,489,615, electro-thermal feedback is utilized for removing thermal conductance between an absorber element of a bolometer pixel in a thermal radiation sensor assembly and the environments through its mechanical support structure and electrical interconnects, thereby limiting the thermal conductance primarily through photon radiation. Zeroing the thermal conductance associated with the mechanical support structure and electrical interconnects is achieved by electro-thermal feedback that adjust the temperature of an intermediate stage and the mechanical support structure as well as the electrical interconnects to equal the bolometer's absorber element temperature.


SUMMARY

Accordingly it is an object of the present invention to provide an improvement in electromagnetic radiation sensors.


It is a further object of the invention to provide an improvement in radiation sensors for detecting thermal radiation in the millimeter (MM) wave spectrum.


It is yet another object of the invention to provide an ultra sensitive silicon MM wave sensor including electrothermal feedback for providing passive imaging of an object through various types of environments.


And it is yet a further object of the invention to provide an ultra sensitive silicon sensor adapted for operation for example at, but not limited to, 30 GHz, 94 GHz, and 220 GHz.


These and other objects are achieved by a method and apparatus including a two tier ultra sensitive silicon sensor comprising: a heat bath for the sensor; an antenna element for receiving thermal radiation; an absorber element coupled to the antenna element for detecting thermal radiation; and an intermediate stage for thermally isolating the absorber element from the heat bath. The antenna is directly mounted on the heat bath approximately coplanar with the absorber element and the intermediate stage. Support elements mutually separate the absorber element, the intermediate stage, and the heat bath. The intermediate stage includes a electro-thermal feedback circuit including a transistor ampifier for reducing the thermal conductivity between the absorber element and the heat bath by causing the temperature of the intermediate stage to converge to the temperature of the absorber element when detecting thermal radiation, effectively causing the thermal conductance of the support elements to attain a minimum conductance value and thereby maximize the sensitivity of the absorber element to the thermal radiation limit. Temperature sensing is achieved by using the forward voltage of a diode in place of the heretofore used thermal EMF voltage. A plurality of these sensors are intended to fuse in an imaging array.


Further scope of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood, however, the detailed description and the specific examples, while indicating the preferred embodiments of the invention are made by way of illustration only, since various changes and modifications coming within the spirit and scope of the invention will become apparent to those skilled in the art from the detailed description.




BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully understood when considered in conjunction with the accompanying drawings which are provided by way of illustration only and are thus not meant to be considered in a limiting sense, and wherein:



FIG. 1 is a diagram illustrative of a conventional bolometer type sensor which is attached to a thermal isolation bridge sitting on top of a substrate including a heat bath;



FIG. 2 is a thermal equivalent circuit for the bolometer shown in FIG. 1;



FIG. 3 is an electrical noise equivalent circuit of the sensor shown in FIG. 1;



FIG. 4 is an electrical block diagram illustrative of an electro-thermal feedback circuit for a bolometer type sensor in accordance with the subject invention;



FIG. 5 is a diagram illustrative of a two-tier bolometer type sensor illustrative of the preferred embodiment of the subject invention;



FIG. 6 is an electrical circuit diagram illustrative of the electro-thermal feedback circuit implemented in the bolometer sensor shown in FIG. 5;



FIG. 7 is a thermal equivalent circuit of the embodiment of the invention shown in FIG. 5;



FIG. 8 is a thermal equivalent circuit for the noise sources due to thermal fluctuations in the embodiment shown in FIG. 5;



FIG. 9 is an electrical circuit diagram of the bipolar transistor circuitry included in the amplifier shown in FIG. 6;



FIG. 10 is a functional equivalent circuit of the electro-thermal feedback circuit shown in FIG. 9; and,



FIG. 11 is an electrical circuit diagram of an array of pixels shown in FIG. 5.




DETAILED DESCRIPTION OF THE INVENTION

With improved thermal isolation, performance of bolometers will directly improve and thereby open a wider range of applications, such as the application of bolometers as passive millimeter (MM) wave staring imagers. Accordingly, means are now presented for greatly improving the thermal isolation in bolometers. This requires within each bolometer pixel, the zeroing of the thermal conductance of an MM pixel between the detector and its mechanical support and readout structures. Achieving improved thermal isolation to the radiation limit will lead to at least a ten-fold improvement in performance. Zeroing the thermal conductance associated with the mechanical support and readout structures is achieved in the subject invention by introducing an improved intermediate stage and electrical-thermal feedback over that shown and described in U.S. Pat. No. 6,489,615 which vary the temperature of the intermediate stage to track changes in the detector's temperature thereby zeroing the net heat flow through the mechanical support and readout structures. This electrical-thermal feedback between the temperatures of the intermediate stage and the detector is achieved, moreover, in an ultra sensitive silicon sensor (USSS) which can be used in passive millimeter wave imagers. The advantages and performance provided by this invention will become evident from the analysis to follow. We begin by first reviewing the performance and limitations of conventional bolometers and then follow with the performance and advantages of the ultra sensitive silicon sensor (USSS).


Conventional Bolometers


A conventional bolometer pixel, and its thermal equivalent circuit, are shown in FIGS. 1 and 2. The bolometer pixel 9, as shown in FIG. 1, includes an absorber element or detector 10, represented by a rectangle with area that is mechanically supported by a low thermal conductance bridge 12, which sits atop of and is anchored to a thermal bath member 14 having a temperature THB. Radiation power hν incident on the detector 10 from a scene Ts is absorbed and changes the detector's temperature by δTD, from TD. As shown in FIG. 2, the detector's heat capacity is C1 and the thermal conductance of the bridge 12 to the heat bath 14 is G1. The scene, at temperature TS, is radiating energy hν at the detector 10 and this is represented in FIG. 2 as a thermal current Q R. The detector 10, in addition to being mechanically attached to the heat bath 14 by the bridge's thermal conductance G1, is radiating power Q1 and receiving QS1, from the shields, not shown.


For the following analysis which involves the thermal equivalent circuit shown in FIG. 2, radiation power is represented as current source Q1, QS1 and Q R1, the thermal conductance between the heat bath 14 at THB and detector 10 at TD as a thermal resistance with a conductance G1. The temperatures Ts, TD, THB are treated as voltages. With such an equivalent model, the performance of the bolometer pixel 9 (FIG. 1) can be analyzed with the well developed techniques used for electronic circuits as follows.


Signal Level in Conventional Bolometers


The detector's signal is dependent on the absorbed incident photon flux power, and this is given by QR=σTS4AD/4F2, where σ=5.6697×10−8 W-m−2-K−4, Ts is the scene temperature, and F is the optic's F#. Additionally, radiation power is incident onto the detector 10 from the shields, and it is given by QS1=σTHB4AD[1−1/4F2]. Similarly, the detector 10 radiates power to the environment, and this is given by QD1=σTD4AD. Functional differences between the expression for QR, QD1, and QS1 are because the radiated power is through different solid angles, accounted for by the lens's F#. Additionally, the detector 10 also conducts thermal energy, through conductance G1, to the heat bath 14, at temperature THB.


Analytically, the thermal conditions at the bolometer are represented as:
QR-QD1+QS1=THBTDG1(T)T+TDTD+δTDjωC1(T)T=n=0[nG1(THB)THBn(TD-THB)n+1(n+1)!+jωC1(TD)TDn(δTD)n+1(n+1)!](1)


The temperature dependence of G1(T) and C1(T) have been included in Equation 1. For conventional bolometers shown, for example, in FIG. 1, it is assumed that the derivatives of G1(T) and C1(T) are a weak function of temperature and for simplicity only first order terms are retained. At equilibrium, or constant radiation power conditions, the detector's equilibrium temperature TD0 is obtained from Equation 1, for ω=0, and is given by:
TD0=THB+QR+QS1-QD1G1+0.5G2(T)T(TD0-THB)(2)


Thus, at equilibrium, the detector's temperature will be different from the heat bath temperature by the net power flow divided by the conductance G1, measured at TD0. As expected, the more power received by the detector 10, the higher will be its operating temperature, since it is directly proportional to the incident power, QR+QS1>QD1. Since QS1 is fixed in temperature, the detector's temperature will change monotonically with changes in scene temperature TS; and changes in the detector's temperature are maximized with minimum conductance G1.


Under dynamic conditions, a detector's operation is characterized by relating dynamic changes in the scene's temperature δTS to dynamic changes in the bolometer's temperature δTD, about the thermal equilibrium temperature TD0. We assumed that the radiation shield is held at a constant temperature δTHB=0, hence no contribution are made by ∂QS1/∂T=0. Taking the differential of remaining terms in Equation 1, at temperature T10, we obtain a relationship between δTD and δTS given by:
δTD=GRGD1+G2δTS[1+jω(C1GD1+G1)](3)


The other variables in Equation 3 are: GR=∂QR/∂TS=σTS3AD/F2 is the conductance of thermal radiation through space from the scene; GD1=∂QD1/∂T1=4σT13AD is the conductance of thermal radiation through space from the detector.


Equation 3 relates the dynamic changes in the scene's temperature δTS to changes in the detector's temperature change δTD. The detector's signal δTD is monotonically related to δTS, and the maximum signal possible is when δTS=δTD. The attenuation from unity gain is represented by coefficient GR/[GD1+G1]. AC response dependent on the thermal time constant and is given by the radial frequency (ωTM=[GD1+G1]/C1. The signal attenuation occurs because a large fraction of power received from the scene (corresponding the detector's footprint on the scene) is drained away through conductances GD1 and G1. For maximum signal, conductances GD1 and G2 should approach in value GR.


Accordingly, much effort has gone into minimizing the thermal conductance G1. Geometrical approaches coupled with selecting materials with poor thermal properties are used toward achieving this goal. Constructing detectors with very small mass minimizes C1 and AC attenuation. However, the size of C1 inversely impacts the thermal noise level at the detector and, therefore, it should not be made arbitrarily small. The maximum signal and minimum noise design criteria, given in terms of GD1, G1, and C1, is developed from the noise analysis given below.


Noise Level in Conventional Bolometers


Several noise sources contribute to the total temperature variance at the detector 10 and all these contribute and limit the detector's sensitivity. The noise sources include: (1) variance in the scene's photon power absorbed by the absorber element, δQ2R, (2) variance in the photon power emitted by the absorber element, δQD12, (3) variance in the radiation shield's photon power absorbed by the detector, δQS12, (4) variance in the thermal bath 14 temperature, δTHB2, and (5) variance in the detector's temperature produced by noise in readout electronics, δTEL2.


Each of these noise sources causes sensitivity degradation and they are examined below. The effects of the various noise sources are quantified in terms of their contribution to the detector's temperature variance. Quantification in terms of the detector's temperature variances, is appropriate for the bolometer's sensitivity is typically given in terms of noise equivalent temperature resolution (NEΔT). Thus, the photon flux variance, from the scene, δQR2, the detector, δQD12, and the shields, δQS12, produce temperature variances at the absorber labeled as: δTS2, δT12, and δTS12, respectively, and are computed below.


(I.) Scene fluctuations in the power emitted increase the detector's temperature variance. Fluctuations in the scene's output power impose the ultimate limit on the bolometer's sensitivity, represented in terms of NEΔT. The best, smallest NEΔT is achieved when all other noise sources, including noise from the detector 10, are much smaller than noise from fluctuations in scene's photon flux. Thus the minimum noise level corresponds to the noise variance δQ2R of the signal power Q R, arriving from the scene and absorbed by the detector 10, and is given by:
δQR2=8ADσkBTS5Δf4F2(4)

    • where, Δf represents the electrical frequency bandwidth of the detector 10 and kB is Boltzmann's constant. The denominator accounts for the fact that only a fraction of the signal reaches the detector 10 and the size of the fluctuation is reduced as is the photon signal emitted by the scene.


Fluctuations in the scene output power is readily translated into a temperature variance at the detector 10, and this represents background limited performance. Temperature variance at the detector induced by the scene δTS2 is obtained by combining Equations 3 and 4 and integrating over frequency. Specifically, the temperature fluctuations δTS2, at the detector, is produced by the scene radiation variance δQR2 and is given by:
δTS2=2πF20ADσkBTS5[GD1+G1]2+ω2[C1]2ω=GR(GD1+G1)·kBTS2C1(5)


Equation 5 reveals that the temperature variance, induced by the scene on the detector 10, is a product of two factors. The first factor is the ratio of free space conductance to the conductance between the detector 10 and thermal bath 14: GR/[GD1+G1. The second factor corresponds to the temperature variance of an object at temperature Ts and with heat capacity C1. For best performance, the noise from the scene should dominate over all other noise sources. This is facilitated with a fast lens (small F#) and minimum conductance [GD1+G1] (absorber element 10 with good thermal isolation).


(II.) Variance in the detector's temperature δT12 is produced by several sources, and this includes: (1) thermal conductance G1 between the detector 10 and heat bath 14, (2) radiative conductance GD1 between the detector 10 and radiation shields, not shown, and (3) radiative conductance GS between the detector 10 and scene, just considered. Here, we focus on temperature variances due to thermal conductances G1, and GD1.


At the detector 10, the spectral density of temperature variance δT12(f) is given in terms of the different conductance paths between the detector 10 and surroundings. The expression for the spectral temperature variance is given as:
δTD2(f)=4kBTD2[G1+GD1][G1+GD1]2+[ωC1]2(6)


The integral of Equation 6 yields the thermodynamic expression kBTD2/C1, corresponding to the temperature variance of an object at TD with a heat capacity C1. However, this total temperature variance includes contributions from radiative and thermal conductance paths. The radiative part is included by the GD1 term in the denominator of Equation 6. Two contributors are included in GD1, one from the scene and the other from the radiation shields. Hence, GD1=GR+GS1, where GS1 is the conductance between the radiation shield and the detector 10. Performing the integration with respect to radial frequencies ω, we obtain for δTD2:
δTD2=12π04kBT12[G1+GD1][G1+GD1]2+[ωC1]2ω=kBTD2C1(7)


Thus the detector's temperature variance, δT12, reduces to the theoretical temperature variance of an object at temperature TD and with a heat capacity of C1.


(III.) Fluctuations in power from the antenna 20 and housing (radiation shield), surrounding the absorber element, contribute to the overall temperature variance. Photons from the antenna 20 are indistinguishable from photons form the scene, represented by Equation 4. The temperature variance, produced by these fluctuations, is readily estimated in terms of the radiation conductance between the detector 10 and shield, GS1=GD1−GR. Proceeding as with Equations 6 and 7, the expression for temperature variance δTS12, at the detector 10, due to the radiation shield held at temperature TS1, becomes:
δTS12=12π04kBTS12[GD1-GR][G1+GD1]2+[ωC1]2ω=[GD1-GRG1+GD1]kBTS12C1(8)


The temperature variance δTS12 is given as a product of two factors. The first factor indicates that this contribution is attenuated by the ratio of GS1=GD1−GR to the total conductance, GS1+GD2. The second factor is the theoretical temperature variance of an object at temperature TS1 and with a heat capacity of C1. Typically, the radiation shield's temperature equals to the heat bath 14 temperature, THB. Hence, we typically substitute THB for TS1, in Equation 8.


(IV.) Thermal bath fluctuations contribute to the variance in detector's 10 temperature. The temperature variance δTHB2 in the temperature of the heat bath 14 THB (FIG. 1) is given as:
δTHB2=kBTHB2CHB(9)

    • where, CHB is the heat capacity of the heat bath 14. The variance δTHB 2 can be made small by increasing the mass of the heat bath 14, and in principle this can make δTHB2 arbitrarily small relative to the other noise sources. This is particularly important, for the temperature variance in the heat bath is directly coupled to the detector 10. Typically, G1>>GR, GD1, and GS1. Hence, with the equivalent circuit in FIG. 2 this provides direct evidence that the variance δTHB2 modulates the detector's temperature with a coupling coefficient approaching unity. Thus, for all practical purposes, the temperature variance in the heat bath 14 replicates itself as a variance in the absorber element's temperature and is given by Equation 9.


(V.) Noise in the detector's readout circuits contribute to the detector's temperature variance. The readout circuit noise is given by a voltage squared spectral density dENA2/df, which includes 1/f and white noise components. In this analysis, this voltage noise is translated to an equivalent variance in temperature at the bolometer. This translation from variances in voltage to variances in temperature facilitates the analysis and the computation of NEΔT. Translating the readout circuit's voltage noise into an equivalent variance in temperature requires consideration of the actual readout circuits and the bolometer. In this analysis, consistent with the fact that resistive bolometers are the most widely used, we analyze the performance of a conventional resistive bolometer.


Resistive Bolometer


The readout circuit's voltage noise corrupts the output from a resistive bolometer, biased with a dc current ICR. For improved understanding, the corruption produced by electronic circuit noise is transformed into an equivalent temperature variance. This equivalent variance in the absorber element's temperature, caused by electronic voltage noise, is labeled as δTEL2.


The total electrical noise presented at the readout circuit, shown in FIG. 3, is a sum of spectral voltage noise variances from the bolometer dE2N/df and amplifier dE2NA/df. The voltage noise from the bolometer is filtered by the circuit capacitance CE, and is in series with the noise form the amplifier. The equivalent temperature variance produced by the voltage noise at the readout amplifier's input is:
δTEL2=1[ICRRCBTS]2·12π0[EN2f1+(ωCERE)2+ENA2f]ω(10)

    • where, the leading factor in Equation 10 converts the variance in voltage noise to a temperature variance by dividing by ICR∂RCB/∂TS, squared, where ∂RCB/∂TS represents the resistive temperature coefficient, and ICR is the dc bias current flowing through the bolometer during readout. The second factor in Equation 10 contains the variances of the bolometer and the amplifier's voltage noise spectral density.


For best performance, the bolometer's resistive temperature coefficient ∂RCB/∂TS should be made large, for this directly attenuates the contributions of voltage noise to the temperature variance. See Equation 10. Making the bolometer's dc bias current ICR large, helps in principle, but has practical problems in that the associated I2R heating is much larger (>1000×) that the IR signal and requires pulsed operation (wider noise bandwidth) of the absorber element's readout circuits. Additional noise reduction is achieved by selecting readout amplifiers with spectral voltage variances dE2NA/df smaller than the bolometer's dE2N/df. Such conditions are facilitated with large resistance bolometers. Typically, the bolometer's resistance is greater than 10KΩ, which represents a white noise voltage spectral density of 12.9 nV/Hz1/2. This value does not include 1/f noise terms which complicate the integration of Equation 10. If we assume that only the white noise from the bolometer dominates, then Equation 10 can be readily integrated and the result is given by:
δTEL2=1[ICRRCBTS]2·0.25CERE[EN2f](11)


For the purpose of calculations, we can increase the value of d EN2/df to compensate for 1/f noise components, and we choose to use 0.1 μV/Hz1/2 for the value of d2EN/df. It should be also noted that the value of Equation 11 is proportional to the electrical readout bandwidth given as (ωEL=1/CERE. Ideally, ωEL should equal the thermal mechanical bandwidth ωTM=[GD1+G1]/C1. Typically, the thermal mechanical bandwidth is narrower than the electrical readout bandwidth (ωELTM) by a constant factor KBW, so that (ωEL=KBWωTM.


The bolometer's total temperature variance δTT2 is simply the sum of Equations 5, 7, 8, 9 and 10. If we assume d EN2/df is constant with frequency and after some rearrangements, the equation for δTT2 is given by:
δTT2=(kBTS2C1)·(GRGD1+G1)·{1+(G1+GD1-GRGRTD2TS2+C1CHB(GR+G1GR)THB2TS2+(GR+G1GR)C1kBTS20.25CEREEN2f(ICRRCBTS)2}(12)


Equation 12 had been cast into this form to reveal the relative values of every noise source relative to the noise present in the signal. Equation 12 is made up of a product of three terms. The leading factor is the minimum thermodynamically possible temperature variance at a detector, limited by the detector's heat capacity and scene temperature. The second factor shows how this minimum temperature variance is increased since the detector's thermal isolation is not as good as the conductance between the scene and the detector. The third factor, in the braces, includes different noise sources which increase the absorber element's overall temperature variance. When the expression in the braces equals one, the dominant noise is scene noise.


The temperature resolution of the bolometer is limited by the variance, given by Equation 12, and is simply equal to the standard deviation: the square root of Equation 12. Combining this with the signal amplitude (given by Equation 3) the bolometer's performance is determined. The bolometer's performance in terms of NEΔT is calculated below.


Sensitivity of Conventional Bolometers


The sensitivity of bolometers is given in terms of their temperature resolution NEΔT. The NEΔT is the minimum temperature the bolometer can resolve and occurs when the absolute signal to noise ratio is unity. The signal to noise ratio is readily calculated with Equations 3 and 12. The signal to noise ratio equals the signal induced temperature change in the bolometer, given by Equation 3, divided by the RMS fluctuation in the bolometer's temperature, given by the square root of Equation 12. For unity signal to noise ratio, solving for δTS, the equation obtained for NEΔT is:
NEΔT=ωTMkBTS2GR1+(ωωTM)2{1+(G1+GD1-GRGR)TD2TS2+C1CHB(GD1+G1GR)THB2TS2+C2kBTS2(GD1+G1GR)ωEL4EN2f(ICRRCBTS)2}1/2(13)


The expression for NEΔT has been simplified by incorporating into Equation 13 ωTM=[GD1+G1]/C1 and ωEL=1/RECE. Thus, NEΔT is expressed as a product of three factors. The first factor represents the low frequency thermodynamic sensitivity limit determined by: the thermal bandwidth ωTM, and GR, dependent on the optics F#, the detector size AD, and the scene temperature TS. The second factor indicates how the sensitivity decreases with frequency (ωTM=[G1+G1]/C1. The third factor includes the contributions from various noise sources: (1) noise in the scene signal, (2) noise from the bolometer, including radiation shields, (3) noise from the thermal bath, and (4) noise from the electronic readout circuits.


The NEΔT is expressed as a product of three factors in Equation 13. Maximum sensitivity, i.e., the smallest NEΔT, is achieved by minimizing each of these factors. The middle factor in Equation 13 represents the radial frequency dependence of NEΔT. Optimally, the thermal radial cut-off frequency ωTM should be made equal to the system frame rate. Setting ωTM at the system frame rate will maximize the system's dc sensitivity and this is evident from the first factor in Equation 13. The First factor in Equation 13 dictates that for maximum sensitivity: (1) ωTM be set at a minimum, (2) the optics F# should be as small as possible (fast optics), and (3) the absorber's size AD should be as large as possible, while satisfying system resolution requirements. The third factor explicitly includes all the noise terms and for best sensitivity it should be minimized to unity.


The steps required to minimize the third factor to unity are revealed by examining in detail each of the noise terms. The noise: terms in the third factor are divided into three groups. The first group represents radiation noise from the scene and the absorber (including radiation shields) noise. The minimum noise occurs if the scene noise dominates. This is facilitated by using a small F# (fast optics), operating the detector TD and radiation shields THB colder than the scene temperature TS; however, for equilibrium detectors this is not possible since ideally the detector and scene are in thermal equilibrium.


The middle term in the third factor in Equation 13, represents heat bath noise contributions, coupled through thermal contact G1, to the detector. Reduction of the heat bath noise contributions are readily minimized by making CHB>>C1. By making the heat capacity sufficiently large, the heat bath noise is severely reduced and no other steps are needed to achieve further reductions.


The bottom term in the third factor in Equation 13 represents the readout electronics noise contribution to the detector. Reducing the readout electronics noise below the scene noise in the signal is difficult. The difficulty becomes evident by quantitively examining the bottom term in third factor in Equation 13. Optimistically, let's assume that the noise from the resistive bolometer dominates, and typically for a 104Ω resistor the noise dEN2/df is about 2×10−16V2/Hz. This does not include 1/f noise that makes things even worse. In resistive bolometers, ∂RCB/∂TS≈200Ω/K and G1/GD110. For: TS≈300K, T1≈213K, AD=0.25×10−4 cm2, and F=1; we evaluate the bottom term in the third factor in Equation 13, and obtain: (ωELTM)1.3×10−9/ICR2. This expression, for the electronic noise contribution, should be significantly less than 1 to make electronic noise insignificant. If (ωELTM)=1, the required circuit current ICR>>0.04 mA. If the 1/f noise is included, the required current level is probably ICR>1 mA. With ICR≈1 mA, during readout, the I2R power delivered is about 10 mWatts, verses 0.1 μWatts delivered from the scene This means the readout I2R power is 100 thousand times greater then the power in the signal. This is unacceptable for it introduces thermal stability problems, which can be reduced by reducing readout circuits operational duty cycle. In a staring array, with 400×500 elements, for example, the readout duty cycle can be reduced by up to 2×105 fold to alleviating thermal problems. However the noise bandwidth is increases inversely with readout duty cycle whereas readout noise decreases as a square of the readout current Icr, i.e., (ωELTM)1.3×10−9/IcR2. This solution has practical limitations due to the current capacity of the bolometer and the readout circuit's maximum voltage compliance. Thus, increasing the ICR and decreasing the duty cycle provides insufficient improvements but has practical limitations.


It should be emphasized that the analysis presented for IR bolometers is much less demanding compared to passive MM wave imaging. This can be appreciated by examining Equation 12 where all the noise terms are represented at the detector as temperature variances. In the IR case, GR≅, 10−9 W/K and G1≅2×10−8 W/K. Hence the temperature variance will increase by at least [G1/GR]2≅100, and this is not including electronic noise. In the MM wave region the equivalent value of GR is replaced by GAE≅4×10−12 W/K. The corresponding minimum increase in the temperature variance will increase as [G1/GAE]2≅6×106 or more than 1000 times. This translates the sensitivity of conventional LWIR bolometers from about 25 mK to 25 Kelvin. If electronic readout noise is included, the situation will get even worse. These sensitivity limitations can be overcome with the USSS approach and it is described in the next section.


MM Ultra Sensitive Silicon Sensor

It is evident from the previous discussion on NEΔT (see Equation 13) that the bolometer's sensitivity is reduced by the ratio (GD1+G1]/GR. Similarly, the photoresponse amplitude, see Equation 3, is also degraded by the ratio GR/(GD1+G1]. Since GD1 and GR are limited by the optics, performance improvements requires the reduction of the thermal conductivity G1 between the absorber element 10 and the heat bath 14 in FIG. 1. Much effort has been invested into minimizing thermal conductivity G1 by utilizing special materials and geometries. Presently, the value achieved for G12×10−8 Watts/K, and this is about ten times larger than GD1. In fact, what is needed, is for G1 to be ten times smaller than GD1. Given the limitations inherent with material and geometrical approaches, further reductions in G1, thermal conductivity between the bolometer and heat bath, require a different approach.


The present invention is directed to an improved approach whereby an ultra sensitive silicon sensor (USSS), included, for example, in an array of pixels (FIG. 11) is fabricated using only silicon technology and electro-thermal feedback is used to substantially reduce the thermal conductivity G1. With the electro-thermal feedback, a ten fold improvement in the thermal isolation of the bolometer pixel can be achieved, with: (1) associated improvements in NEΔT; and (2) an increase in photoresponse amplitude. The operation and performance advantages of an MM-USSS are detailed below.


We begin by elaborating how electro-thermal feedback provides at least a ten fold reduction in thermal conductivity over prior art approaches based only on optimally low conductivity materials and geometries. This explanation is followed by a calculation of the photoresponse and noise levels of a passive MM-USSS. From these calculations, the MM-USSS sensitivity is computed.


Maximum Thermal Isolation Through Electro-Thermal Feedback


Thermal isolation between the absorber element 10 of a bolometer pixel 9 and heat bath 14 shown in FIG. 1 can be significantly improved with the use of electro-thermal feedback. The concept of electro-thermal feedback has been disclosed in the above referenced Bluzer patent, U.S. Pat. No. 6,489,615. Maximizing thermal isolation through electro-thermal feedback in accordance with the subject invention will now be demonstrated by analysis. The analysis of the MM-USSS in accordance with the subject invention will include ac and dc components; however, for simplicity and clarity, the analysis is limited to a dc response.


Referring now to FIGS. 4-6, shown thereat is a bolometer pixel 9 including an absorber element or detector 10, at temperature TD, thermally connected to the heat bath 14, at temperature THB, thorough an intermediate stage 16 at temperature TIN. We assert that by design THB is always less than TD and TIN. In addition to normal effects, the relationship between TD and TIN is most influenced by an electro-thermal feedback circuit, represented by an amplifier 18. The amplifier 18 is used to generate heat QH in the intermediate stage 16. The generated heat is proportional to the difference between temperatures TD and TIN, specifically, QH=A(TD−TIN), where A is the electrical-thermal feedback constant.


The detector 10 at temperature TD receives radiation in several different ways. In the present invention, the detector 10 receives millimeter (MM) wave radiation QAE from the scene indirectly from an ac coupled antenna 20 as shown in FIG. 5 and directly by absorbing black body radiation QD. Also, the detector 10 at temperature TD receives radiation QS1 from the shields and radiates itself into the environment QD1. The intermediate stage also radiates thermal radiation QD2 while receiving thermal radiation QS2 from the radiation shields. Additionally, links G1=G1A+G1B and G2=G2A+G2B, shown as resistive elements 22, 24 and 26, 28, thermally and electrically interconnect the bolometer pixel 9; the detector 10, the intermediate stage 16, and the heat bath 14, as shown. The effective thermal impedance between the detector 10 and the surrounding includes the effect of electro-thermal feedback. The effect of electro-thermal feedback on thermal isolation is calculated from heat conservation equations. The dc heat conservation equation at the intermediate stage 16 is:

(TD−TIN)G1+QH+QS2=QD2+(TIN−THB)G2  (14)


Since the radiation shields and the heat bath 14 are held at the same constant temperature, the terms QS2 and THB are constant in Equation 14. Taking the differential of Equation 14, the relationship between temperatures TD and TIN is computed and is given by:
δTIN=(G1+A)(G1+G2+GD2+A)δTD(15)

    • where GD2=∂QD2/∂TIN is the radiative conductance from the intermediate stage to it's surroundings, and is given by

      δQD2=GD2δTIN=8σAINTIN3δTIN  (16)


With AIN is the intermediate stage front surface area, and σ=5.6697×10−8 W/M2−K4, the Stefan-Boltzmann constant. It should be noted from Equation 15 that if the electrical-thermal feedback constant A is sufficiently large, relative to G1, G2, and GD2, any temperature changes in δTD are tracked and almost replicated by δTIN. The effect of changes in the apparent scene temperature δTS, on the detector's δTD, is obtained from heat conservation at the detector and is given by:

QAE+QD+QS1=QD1+(TD−TIN)G1  (17)


Before taking the differential of Equation 17, we proceed to examine each term. The right side of Equation 17 includes the black body radiation Q1 given off by the detector 10, and the power drained through conductance G1. The differential power radiated directly by the detector 10 is given by:

δQD1=GD1δTD=8σADTD3δTD  (18)


Where AD represents the detectors front surface area. The left hand side of Equation 17 includes three terms, one constant and two variable terms. The term QS1 (δQS1=0) is a constant since the shields are maintained at a constant temperature. The variable terms QD represents the black body radiation received by the detector 10 directly and its differential is given as:
δQD=GDδTS=2σADTS3F2δTS(19)

    • where, F is the optics F-number and Ts is the actual change in scene temperature. The term QAE represents the MM wave radiation received by the detector 10 from the antenna 20. Since the MM wave energy hν<<kTS, the Planck expressions can be simplified. Integrating the radiation received over the operating frequency bandwidth, we obtain a simple expression and it is given by:
      QAE=ɛηAPkTS(v23-v13)3F2(c/N)2(20)


Where: “k” is Boltzmann's constant; “η” represents the antenna efficiency; “c” is the speed of light. “N” is the index of refraction; “ν2−ν1” is the operating bandwidth of the antenna 20; AP is the antenna area and is substantially equal to the pixel area; ε is the objects emissivity; and TS is the scene temperature.


In IR the emissivity is approximated as unity. In the MM wave region the emissivity changes and we can assume, conservatively, that the emissivity varies about δε/ε≅10%. Taking the differential of QAE and including contributions from emissivity and scene temperature variations we obtain:
δQAE=ηAPk(v23-v13)3F2(c/N)2(ɛδTS+TSδɛ)ηAPk(v23-v13)3F2(c/N)2(δTS+TSδɛ)(21)


The right side of equation 21 include a term δTS+TSδε=δTSS where we define δTSS as the equivalent radiometric temperature. It should be noted that the equivalent radiometric temperature can be much larger that the actual change in temperature δTS. In this analysis for mm wave performance we will be always using the equivalent radiometric temperature TSS. Taking the differential of Equation 17, we obtain a relationship between changes in the apparent scene temperatures TSS, the detector's temperature TD, and intermediate stage temperature TIN and these are given by:

GAE δTSS+GDδTS=(GD1+G1TD−G1δTIN  (22)


Where G1=∂QD1/∂TD GD=∂QD/∂TS. As will become evident later, we neglect GD because GD<GAE. Combining Equations 15 and 17, the intermediate stage temperature differential, δTIN, is eliminated, and we obtain a relationship between δTSS and δTD given by:
δTD=GAEGD1+G1(G2+GD2G1+G2+GD2+A)δTSSGAEGD1+G2G1AδTSS(23)


The advantages of electrical-thermal feedback are illustrated by Equation (23). For a large electrical-thermal feedback constant A[A>>{G1, G2, GD2}], the denominator in Equation 23 reduces to GD1. If no electrical-thermal feedback were utilized [A=0] the denominator in Equation 23 increases to GD1+G1G2/(G1+G2)−0.5G1. Thus large electrical-thermal feedback severely attenuates the thermal shunting effects produced by G1 and G2, thereby effectively increasing the detector's thermal isolation from 0.5G1 to GD1. The increase in thermal isolation is best appreciated if we numerically examine Equation (23).


The numerical values of GAE, G1, G2, GD1, GD and GD2, are computed with Equations 16, 18, 19, 21. The values for G1 and G2, based on experience, are approximated as 10G1≈G2≈10−7 W/K. We compute (details follow) for A≈10−5 W/K. For AP representing a 1 MM square pixel coupled through an antenna 20 (see FIG. 5) and a lens, not shown, with an index of refraction N=10 and F=1, we obtain GAE≅4.2×10−12 W/K[assuming a 30 GHz bandwidth, centered at 95 GHz and 100% coupling efficiency]. The detector at temperature TD will be made small about 5 μm in diameter. It follows that GD≅6×10−11 W/K and GD1≅2.4×10−10 W/K. The value of GD2≅2.4×10−9 W/K because the intermediate stage will be about 10 times larger in size than the detector. Gathering these numerical values, we examine the two limits of Equation 23: with and without electrical-thermal feedback and obtain:
δTD{12×10-3TSSwithfeedback42×10-6TSSnofeedback}(24)


Equation (24) dramatically illustrates the effect of electrical-thermal feedback: for a given change in equivalent radiometric temperature, δTSS, the response signal at the detector, δTD, is increased more than 250 fold because of greatly diminished effects of thermal loading on the detector.


Using the principal of electro-thermal feedback, improved thermal isolation is achieved and the degree of isolation achieved is beyond the isolation possible through optimizing thermal insulating by materials and/or geometrical approaches. Incorporating the principal of electro-thermal feedback, we proceed to present and analyze the performance of a millimeter (MM) wave ultra sensitive silicon sensor (USSS) pixel in accordance with the subject invention.


MM USSS Pixel Embodiments and Operating/Readout Electronics


Incorporation of electro-thermal feedback to form an ultra sensitive silicon sensor in accordance with the subject invention as shown in FIGS. 5, 6 and 9 requires combining special circuits within each bolometer pixel 9. Specifically, electro-thermal feedback requires: (1) a temperature difference sensor, (2) a temperature difference amplifier, (3) a heater with an output dependent on temperature difference, and (4) a structure which incorporates items 1 through 3 into a single pixel.


With respect to (4) above, in FIG. 5, the USSS pixel 9 in accordance with the subject invention utilizes a two-tier design for simplifying fabrication and maximizing area efficiency, and is shown including a detector element 10 at TD ac coupled via ac coupling means 11 to an antenna 20, and having a flat upper absorber portion with a predetermined surface area, an intermediate stage 16 at TIN adjacent to the detector element 10 and a heat bath 14. The heat bath at THB includes a substrate portion 15 and an annular upper body portion. Support elements or links 22, 24 and 26, 28 respectively couple the detector 10 to the intermediate stage 16 and the intermediate stage 16 to the upper portion 17 of the heat bath 14, providing conductances G1A and G1B and G2A and G2B. The intermediate stage 16 and the detector 10 are substantially coplanar and are mounted in a generally circular cavity 30 of the upper body member 17 of the heat bath 14 being secured to the inner wall surface 32 via the support elements 26 and 28. The antenna element 20 is shown comprising a generally flat member located on the outer surface 34 of the upper body member 17 of the heat bath 14 and is substantially coplanar with the detector element 10 and the intermediate stage 16.


The USSS pixels 9 shown in FIGS. 5 and 9 are intended for incorporation into an array with readout electronics for accessing the output of each individual pixel. An x-y array of pixels 9 is shown in FIG. 11 and includes x-y address switches 42 and 44 for reading out each pixel 9. Conventional address circuits, column and row shift registers utilized with such an array are not shown. Such an array is capable of passively imaging electromagnetic radiation emanating from a scene, for example, at millimeter wavelengths.


Since operation is intended for imaging in the millimeter (MM) wave portion of the electromagnetic spectrum, the pixel size of a pixel 9, as shown in FIG. 5, is on the order of 250 times the size of a pixel shown and described in the above referenced U.S. Pat. No. 6,489,615 and which is intended primarily for operation at LWIR.


The temperature difference sensor in the subject invention utilizes two silicon diodes 30 and 40 connected back to back, to measure the temperature difference between the detector 10 and the intermediate stage 16. One diode 38 is incorporated in the detector 10, and the second diode 40 is incorporated in the intermediate stage 16, as shown in FIG. 6. Biased with a constant current, each of the silicon diodes 38 and 40 exhibit a temperature dependant voltage that follows changes in the Fermi level. The Fermi level's temperature dependence produces a temperature dependent potential difference between the n-side conduction band and the p-side conduction band. The temperature dependent voltage change across a diode, biased with a constant current, is typically about −2.3 mV per degree Kelvin. Utilizing the two diodes 38 and 40, connected back-to-back, as shown in FIG. 6, provides a measure of the temperature difference between the detector 10 and intermediate stage 16. This temperature difference produces an input voltage that is amplified by the amplifier 18, and outputs an output voltage VO.


The amplifier 18 in the subject invention includes a bipolar transistor circuit 42 as shown in FIG. 9 which not only amplifies and provides an output signal VO, but its quiescent power consumption serves as a heater for the intermediate stage 16, thereby mechanizing the electrical-thermal feedback loop. This dual function is made possible by designing the amplifier circuit 18 including the bipolar transistor 42 to operate at equilibrium at a constant current IH. Operating the amplifier 18 at a constant current IH insures that the output voltage is not only a measure of the temperature difference between the detector 10 and intermediate stages, but also determines the thermal power QH delivered to the intermediate stage 16. The thermal power QH, delivered by the amplifier 18 to the intermediate stage 16, is simply given by:

QH=IHVO=IHAG[2.3mV/K(TD−TIN)]  (25)


where, AG is the amplifier's voltage gain and IH is the amplifiers operating dc bias current. The amplifier's low frequency voltage gain is typically about 105 and IH is about 1 μA. Since IH is held constant, as TD>TIN (TD<TIN) VO increases (decreases) the amplifier's quiescent power, causing heating (cooling) of the intermediate stage 16. The intermediate stage's bipolar transistor's temperature operation (heating and cooling) is made possible by adjusting the temperature of the heat bath 14 to be always lower that any object in the scene: THB<{TD, TIN}. Thus the combination of the amplifier 18 and heat bath 14 provides the desired bipolar temperature operation.


The differential representation of the electrical-thermal feedback is obtain by taking the differential of equation (25) which is expressed as:

δQH=IHAG[2.3mV/KTD−δTIN)]=ATD−δTIN)  (26)


The electrical-thermal coefficient, A, is readily evaluated by using AG≈105, IH≈10−6 amp. Substituting these values into equation (26) we obtain A≈10−5 W/K, and this is much larger than G1=G1A+G1B or G2=G1A+G1B by about 1000 times.


Thus by utilizing three temperature platforms, i.e., the detector 10 at TD, intermediate stage 16 at TIN, and heat bath 14 at temperature THB, the thermal electrical feedback adjusts the power QH applied to the intermediate stage 16 to make its temperature, TIN, converge to the detector's temperature, TD. Minimizing the temperature difference between the detector 10 and the intermediate stage 16 effectively makes the conductance G1=G1A+G1B go to zero.


MM USSS AC Response


The AC response is computed from an analysis on a thermal equivalent circuit of FIGS. 5 and 6 as shown in FIG. 7. The analysis follows an approach similar to the analysis previously presented for a conventional bolometer. The analysis implicitly assumes that THB is always less than TD and TIN. The analysis demonstrates that electrical-thermal feedback severely attenuates the conductance of G1, thereby leading to at least a 25-fold improvement in thermal isolation and increased response. The heat capacity of the detector 10 is represented by C1 and the intermediate stage's heat capacity is represented by C2. QAE represents the radiation power from the scene delivered through the antenna 20 and coupled to the detector 10. QD represents the radiation power directly absorbed by the detector 10. QS1 and QS2 represents the radiation power from the radiation shields absorbed by the detector 10 and the intermediate stage 16. Q1 and QD2 represents the radiation power emitted by the detector 10 and the intermediate stage 16. QH is the power delivered by the electrical-thermal feedback circuit.


The thermal balance conditions at the detector 10 and intermediate stages 16 are expressed in terms of two integral equations. At the detector 10, the equation for thermal balance is given by:
QD+QAE-QD1+QS1=-TDTING1(T)T+TDTD+δTDjωC1(TD)TD=-n=0(nG1(TD)TDn(TIN-TD)n+1(n+1)!)+n=0(jωnC1(TD)TDn(δTD)n+1(n+1)!)(27)


Taking the small temperature change limit, the G1 and C1 integrals in Equation 27 are approximated by taking only the Taylor series terms linear with temperature. Using this approximation, and taking the temperature differential of Equation 27, we obtain a simplified expression which is given by:

GAEδTSS+GDδTS=[G1+GD1+jωCD]δTD−G1δTIN  (28)


From previous discussion, we found GAEδTSS>>GDδTS, hence GDδTS can be neglected. Similarly, thermal balance conditions at the intermediate stage give rise to an integral equation given by:
-QD2+QH+QS2=-TINTHBG2(T)T+TINTIN+δTINjωC2(TIN)TIN+TDTING1(T)T=-n=0(nG2(TIN)TINn(THB-TIN)n+1(n+1)!)+n=0(jωnC2(TIN)TINn(δTIN)n+1(n+1)!)+n=0(nG1(TD)TDn(TIN-TD)n+1(n+1)!)(29)


As in Equation 27, taking the small temperature change limit, the integrals for G1, G2, and C2 are approximated by only the Taylor series terms linear in temperature. Taking the temperature differential of Equation 29 and combining with Equations 26 and 16, we obtain a simplified expression which is given by:

[G1+A]δD=[G1+G2+GD2+A+jωC2]δTIN  (30)


Since A>>{G1, G2, GD2}, it becomes evident from Equation 30 that the electrical-thermal feedback forces δTD≈TIN. Under such conditions the thermal current through G1 is not changed even though the temperature TD of the detector 10 changes. The improvement in thermal isolation is explicitly revealed combining Equations 29 and 30 to eliminating TIN. Combining Equations 29 and 30 to eliminate TIN, after some rearrangements we obtain an expression for TD as a function of TSS, specifically:
δTD=GAE[GD1+jωC1+G1[G2+GD2+jωC2][G1+G2+GD2+A+jωC2]]δTSS[GAEGD1][1+jωC1GD1]δTSS(31)


Equation 31 reveals that for large thermal electrical feedback values, A>>{G1, G2, GD2}, the change in radiometric scene temperature δTSS is related to δTD by an approximation represented by the right side, of Equation 31. This comes about because the temperature of the intermediate stage 16 of TIN tracks change in the temperature of the detector 10, effectively making the thermal conductance of G1 seem much smaller. Except for limits imposed by noise, the thermal conductance G1 should approach zero as A goes to infinity.


For the values used here, A ≈10−5 W/K (see Equation 26) is much larger than the typical values of 10G1G2≈10−7W/K. Therefore, actions of the thermal electrical feedback reduces conductance G1≈40GD1, below the conductance GD1. This reduction leads directly to at least a 40-fold response increase, as evident from comparing the denominators in Equations 3 and 31. The increased response is evident from the change in the detector's temperature δTD in response to a change in radiometric scene temperature δTSS(see Equation 31). The increased responsivity produces an important benefit, since it provides signals much improved to corruptions by various noise sources, thereby leading directly to improved sensitivity.


The AC temperature response of the detector 10, given by the approximation in Equation 31, is according to the time constant C1/GD1. For TV frame rates, this requires the heat capacity of the detector 10 be minimized. With the antenna 20 as shown in FIG. 5, the size of the detector can be minimized without affecting significantly the MM wave signal. In particular, the size of the detector 10 in accordance with a preferred embodiment of the subject invention as shown in FIG. 5, will be about 5 μM in diameter, much smaller that the anticipated size of the pixel 9, about 1000 μM square. This approach is viable to realizing a time constant consistent with TV frame rates, e.g., 0.167 seconds.


With the interrelationships between δTD, δTIN, and δTSS, given by Equations 30 and 31, we will now proceed to compute the MM USSS voltage response. The power QH, delivered by the electrical-thermal feedback amplifier 18 provides the output signal VO. Changes in the power δQH delivered by the electrical-thermal feedback circuit is related simply to the output signal δVO by the bias current IH, since δQH=−δVOIH, see Equation (26). Incorporating this relationship into Equation 30, and after some rearrangement, we obtain an expression for the output signal dependence on δTD, δTIN, which is given as:

δVOIH=G1δTD−[G1+G2+GD2+jωC2]δTIN  (32)


Voltage responsivity is obtained by eliminating δTIN and δTD by replacing them with δTSS. The replacement is accomplished in two steps. First, using Equation (30), we replace δTIN by δTD. Second, using Equation (31), we replace δTD by δTSS. Performing all these substitutions, and after some rearrangements, the MM USSS responsivity is expressed by:
δVO(ω)δTSS(ω)=AGAEIH[1+(G1+A)(G2+GD2+jωC2)](GD1+jωC1)+G1(G2+GD2IH)(GAEGD1)[1+jωC2G2+GD2][1+jωC1GD1]Volts/Kelvin(33)


The approximations for Equation 33 are made possible by using the fact that A>>{G1, G2, GD2}. Several features become evident by examining Equation (33). The output voltage VO is a product of two factors and two time constants.


The first factor reveals that the voltage responsivity increases with higher thermal conductance G2 and lower bias current IH. This occurs because for a given change in radiometric scene temperature δTSS the power that the amplifier 18 has to deliver to the intermediate stage 16 increases with higher thermal conductance G2. Since IH is fixed, the only way the amplifier 18 can deliver more power is by increasing the output voltage VO. Hence it appears as though the voltage responsivity has increased, at the cost of more power consumption per each pixel, and or higher dc operating voltage.


Similarly, the voltage responsivity varies inversely with IH Because, for a given change in radiometric scene temperature δTSS and a constant thermal conductance G2, the power that the amplifier 18 has to deliver to the intermediate stage 16 remains constant. As we decrease IH the amplifiers output voltage needs to increase to keep constant the power delivered.


The two time constants in Equation (33) are a pole, representing the time constant of the detector 10, and a zero, representing time constant of the intermediate stage 16. The time constant of the detector 10 will case the voltage responsivity to decrease. If the detector 10 had zero heat capacity, (C1=0) the rise in the detector's temperature would correspond to the radiation power supplied divided by the thermal loading on the detector, given as GD1. However, before the detectors temperature can change, the detector's heat capacity, C1, need to receive (it TD increases) or release (if TD decreases) energy and this delay manifest itself as a decrease in the ac voltage response.


The second time constant in Equation (33) represents the time constant of the intermediate stage 16. This time constant has the opposite effect to the detector's time constant: it increases the voltage responsivity. This can be understood by examining the operation of the electrical-feedback circuit. If the heat capacity of the intermediate stage 16 is zero, C2=0, the temperature rise of the intermediate stage is simply the output power provided by the electrical-feedback circuit (or VOIH) divided by the thermal loading (G2+GD2). However, since the heat capacity C2≠0, more (less) power need to be supplied to the intermediate stage 16 for an increase (decrease) in detector's temperature. Hence it follows that the amplifiers output voltage of the amplifier 18 will be larger (smaller) if the intermediate stage temperature needs to increase (decrease) to converge to the detector's temperature TD.


In principle and to first order, the two time constants can be used to extend the frequency response of the MM USSS beyond the detector's time constant. This can be achieved by making the time constant of the intermediate stage 16 equal to the time constant of the detector 10.


Noise Level in MM USSS


The noise sources in the MM USSS of the present invention are all the noise sources present in conventional bolometers; however, additional noise is produced by the electrical-thermal feedback output power QH. Specifically, the radiation induced thermal fluctuations noises include: scene's flux QS; radiation shields' QS1 and QS2; the bolometer Q1 of the detector 10; and the QD2 of the intermediate stage 16. We also include thermal fluctuations from the heat bath 14 coupled into the detector 10 through conductance G1=G1A+G1B and G2=G2A+G2B. Finally we include the noise from the electrical-thermal feedback loop. All these noise sources induce temperature fluctuations in the detector's temperature, indistinguishable from a signal. Since the MM USSS output is a voltage signal VO, all the noise terms are itemized and given as a noise voltage.


Specifically, the MM USSS noise is given as RMS voltage fluctuations produced by temperature fluctuations in: (1) the scene, δVO(TSS), (2) the heat bath 10, δVO(THB), (3) the detector 10 stage's temperature δVO(TD), and (4) the intermediate stage's 16 temperature δVO(TIN). Additionally, fifth noise term is from the electrical-thermal feedback and readout circuits contained in each MM USSS pixel δVO(EL). An expression for each one of these noise components is derived and given below.


The overall noise is computed by utilizing the transfer function between the various noise sources and the detector output. We make use of our knowledge of the RMS value of the fluctuations in: radiometric temperature TSS, the heat bath temperature THB, the detector stage temperature stage TD, the intermediate stage temperature TIN, and the readout electronics. Each RMS value is treated as a standard deviation obtained from a Fourier representation of a particular noise fluctuation. Using the principle of superposition, we use the different transfer function, summed over all frequencies, to compute the contribution of each noise source to the detector's output.


(I.) Fluctuations in the radiometric scene temperature, δTSS, contributes noise to the MM USSS output δVO(TSS), and the transfer function for this contribution is given by Equation (33). For maximum frequency response, we would adjust he pole and zero in Equation (33) to cancel. The noise contribution from spectral fluctuations δTSS(ω) in radiometric scene temperature to fluctuations in the detector's output are approximately given as:
δVO(TSS(ω))[G2+GD2IH][GAEGD1]δTSS(ω)(34)


Integrating these contributions over frequency, we obtain the corruption of the detector's output voltage due to RMS fluctuations in the scene temperature δTSS(RMS) and it is given by:
δVO(TSS)[G2+GD2GD1][GAEIH]δTSS(RMS)(35)


Thermal conductance ratios at the detector represented by the ratio GAE/GD1≈0.5 reduces the noise from the scene. However, the signal is also reduced by the same amount thereby increasing susceptibility to corruption by the other noise sources and decreasing the sensitivity.


(II.) Temperature [δTHB(RMS)] fluctuations of the heat bath 14 produce fluctuations in the output signal of the detector 10. This contribution is calculated by using the fact that according to Equation 26 δQH=IHδVO=A[δTD−δTIN]. Thus, by calculating the change produced by δTHB(RMS) on δTD and δTIN we obtain δVO(THB) with Equation 26. Using superposition, and under the conditions that δTHB≠0 and δTSS=δTS=0, we take the differentials of Equations 27 and 29 and obtain the influence of fluctuations in δTHB(ω) on δTD(ω) and δTIN(ω). Spectral representation is used since we intend to sum the different Fourier noise terms to obtain the RMS value. Taking the differential of Equation 27, and after rearranging to simplify, we obtain:

[GS1+jωCHB]δTHB(ω)+[G1]δTIN(ω)=[G1+GD1+jωC1]δTD(ω)  (36)


Repeating the same procedure for Equation 29, we obtain a second equation for the interrelation between the noise terms, and it is given by:

[G2+GS2+jωCHB]δTHB(ω)+[G1+A]δTD(ω)=[G1+G2+GD2+A+jωC2]δTIN(ω)  (37)


In Equation 37, we used the fact that δQH=A[δTD−δTIN]. Solving equations 36 and 37 for δTD(ω) and δTIN(ω) in terms of δTHB(ω), we compute the spectral variations in the output voltage δVO(ω) of the amplifier 18 due to the heat bath 14 as:
δVO(ω)=AIH[(GS1+jωCHB)-(GD1+jωC1)(G2+GS2+jωCHB)(G2+GD2+jωC2)(G1+GD1+jωC1)+(G1+A)(GD1+jωC1)(G2+GD2+jωC2)]δTHB(ω)(38)


This equation is simplified by recognizing that the bath's heat capacity CHB is arbitrarily large. Incorporating this into Equation 38 with the fact that a is very large, we approximate and obtain a simplified expression and it is given by:
δVO(ω)=[G2IH]jωCHB[(GD1+jωC1)]δTHB(ω)(39)


The RMS noise produced by the thermal fluctuations in the heat bath 14 is obtained by using the power spectral density of a thermal body (term inside the integral and the square bracket in Equation 40). Converting Equation 39 into a power spectral density integral, the expression for the output noise voltage produced by the heat bath temperature becomes:
δVO(THB)G2IH0ω2CHB2[4GD1kTHB2GD12+ω2CHB2](GD1+jωC1)2ω2π(40)


Equation 38 can be simplified by recognizing several conditions. The ratio G1/CHB is very small, leading to factorization of the ω2CHB2 terms inside the integral. Incorporating these approximations and integrating over frequency, we obtain a simple relationship given by:
δVO(THB)[G2IH][kTHB2C1]1/2(41)


This represents the RMS fluctuations in the output voltage of the amplifier 18 due to fluctuations in the temperature of the heat bath 14. The level is the minimum thermodynamic noise level possible and surprisingly is independent of the heat capacity of the heat bath 14 and dependent on the heat capacity of the detector 10.


(III.) Fluctuations in the temperature TD of the detector 10 will increase the fluctuations in the output noise voltage. Using the equivalent circuit in FIG. 6, we sum the power at node TD, when δQIN=δQH=0, and obtain the following expression:

δQD(ω)=(G1+GD1+jωC1TD(ω)−G1δTIN(ω)  (42)


Using Equation 28, we eliminate the variable δTIN from Equation 42 and obtain the following expression:
δQD(ω)=[GD1+jωC1+G1(G2+GD2+jωC2)(G1+G2+GD2+A+jωC2)]δTD(ω)(43)


From previous computations with Equation 26, we obtain an expression for the noise voltage produced by temperature fluctuations in TD, and it is given by:
δVO[TD(ω)]IH=A[1-δTINδTD]δTD=A[G2+GD2+jωC2G1+G2+GD2+A+jωC2]δTD(ω)(44)


Combining Equation 44 with Equation 43, we obtain an analytical solution for the spectral noise dependence due to fluctuations in the power δQD, and it is given by:
δVO[TD(ω)]IH=AδQD(ω)[1+(1+A)(G2+GD2+C2)](GD1+C1)+G1(45)


The power spectral density square of δQD is given as d2QD/df=4GD1kB(TD)2, and combining this with the absolute square of equation 45, integrating and taking the square root we obtain the RMS voltage fluctuations in δVO(TD), produced by TD. Performing these operations, with some simplifications, we obtain:
δVO(TD)=G2*+GD2IH[kBTDC1]1/2(46)


(IV.) Contributions from noise fluctuations in δTIN(ω) to the output signal of the amplifier 18 are calculated similarly to contributions from δTD(ω). Using the equivalent circuit in FIG. 8, we sum the power at node TD, when δQD=δQH=0, and obtain a relationship between δTD(ω) and δTIN(ω) given by:
δTD(ω)=[G1(G1+GD1+C1)]δTIN(ω)(47)


Since we are calculating the effect of noise source δQIN, the temperature fluctuations δTIN(ω) in Equation 47 shows that |TIN|>|TD|. Summing the power at node TIN in FIG. 8, we obtain a spectral power relationship given by:

δQIN(ω)+δQH(ω)=[G1+G2+GD2+jωC2]δTIN(ω)−G1δTD(ω)  (48)


Using the fact that δQH=A[δTD−δTIN], and Equation 47, we replace eliminate variable δQH and δTD in Equation 48 and obtain:
δQIN(ω)=[(G2+GD2+C2)+(A+G1)(GD1+C1)(G1+GD1+C1)]δTIN(ω)(49)


Using Equation 26, we obtain an expression for the spectral fluctuations in the output voltage VO[TIN(ω)] produced by thermal fluctuations at node TIN and it is given by:
δVO[TIN(ω)]IH=-A[1-δTDδTIN]δTIN=-A[GD1+C1G1+GD1+C1]δTIN(ω)(50)


Combining Equations 49 and 50, to eliminate δTIN(ω), we obtain an expression for the spectral voltage fluctuations at node TIN in terms of the spectral fluctuations in the black body radiation and this is given by:
δVO[TIN(ω)]IH=δQIN(ω)[1+G1A+(G2+GD2+C2)(G1+GD1+C1)A(GD1+C1)](51)


Since A is very large, Equation 51 reveals that the power associated with the spectral voltage fluctuations equals to the power in the power fluctuations in the black body radiation, regardless of the thermal electrical feedback loop. The power fluctuations at node TIN correspond to the classical temperature variance at TIN times the thermal conductivity from this node to the surroundings. Thus the RMS in voltage VO, due to the thermal fluctuations at node TIN, is given as:
δVO[TIN]=G2+GD2IH[kTIN2C2]1/2(52)


With Equation 52, we complete calculating all the RMS contributions to the output voltage VO of the amplifier 18 produced by temperature fluctuations in THB, Ts, TD and TIN. The remaining noise contribution is from the thermal electrical feedback circuit and this is computed below.


(V.) The noise from the readout and thermal electrical feedback circuit of the preferred embodiment of the invention shown in FIG. 9, including the bipolar transistor 42, contribute noise to the output signal as follows. This contribution is computed with the aid of the equivalent circuit of FIG. 9 shown in FIG. 10. For convenience, all the electrical noise terms have been included into the current generator labeled IN0. This represents the noise present without any form of feedback. Additionally, this analysis is based on the fact that the noise in the circuit can be represented in terms of a Fourier representation with coefficients IN0. Doing the analysis for an arbitrary frequency with amplitude IN0, provides us with the expression for the noise with electrical thermal feedback.


The noise flowing in the circuit is affected by the electrical and electrical-thermal feedback present in the readout circuit shown in FIG. 9. Thus the current noise level without any feedback, INO, (FIG. 10) is modified to a new level in when feedback effects are included and it is given by:

IN0(ω)+[gm+Gm][δVB(ω)−δVO(ω)]=IN(ω)  (53)


Where gM is the bipolar transistors' transconductance and 1/GM is the diode's impedance. The voltage difference between base and emitter has an ac component and a thermal component, because the Fermi levels temperature dependence in the ‘p” and “n” regions of the diode and bipolar transistor. Accordingly, the base-emitter voltage difference for the bipolar transistor is given as:
VB(ω)-VO(ω)=δVO(ω)(Z1Z1+1/gm-1)+VBET(δTD-δTIN)(54)


The first term on the right of Equation 54 represents the electrical division of the output voltage by the diode 38 in series with impedance Z1, under the assumption that the base current is very small. The second term on the right of Equation 54 represents the change in the thermal voltage produced by temperature changes in the diode (TD) and transistor (TIN) temperatures. The coefficient ∂VBE/∂T represent how change in the voltage per degree Kelvin, and typically, ∂VBE/∂T≅−2.3 MV/K. The change in the output voltage δVO(ω) is readily computed by including all the impedances at the output node and the actual noise current flowing, feedback effects included, and this is given by:
δVO(ω)=((1/gm+Z1)ZOO1/gm+Z1+ZOO)IN(ω)(55)


Incorporating Equation 55 into Equation 54, and after rearranging some terms, we obtain a better representation for Equation 53, and it is given by:
INO(ω)=IN(ω)[1+(Gm+gm)ZOO1+gm(Z1+ZOO)]-(gm+Gm)VBET(δTD-δTIN)(56)


Observing Equation 56, it is evident that current IN is smaller that the original noise current IN0 provided the thermal term in Equation 56 is positive, when expressed in terms of IN. In fact, it will become evident that the electrical-thermal feedback term further reduces the noise current, and this is computed below.


Taking Equation 48 under the conditions that δQIN(ω)=0, we obtain a relationship between IN(ω), δTD(ω), and δTIN(ω) and it is given as:

IHδVO(ω)=(G1+G2+GD2+jωC2TIN(ω)−G1δTD(ω)  (57)


We have included a term −IHδVO(ω)=δQH(ω), and it represent changes in power consumed at the intermediate stage caused by a change in the output voltage δVO(ω) for dc current IH flowing into the output node. As the noise current increases, the output voltage decreases, and the quiescent power consumed by the intermediate stage also decreases, hence the minus sign on the left side of Equation 57. Earlier in Equation 47 we expressed a relationship between δTD(ω) and δTIN(ω).


Combining Equations 57 and 47, we eliminate δTD(ω), and obtain δTIN(ω) as a function of IHVO(ω), and it is given by
δTIN(ω)=-IHδVO(ω)(G1+GD1+C1)(G1+GD1+C1)(G2+GD2+C2)+G1(GD1+C1)(58)


The right most term in Equation 56 is expressed in terms of IN(ω) by replacing δTD(ω) with Equation 47, and δTIN(ω) with Equation 58, and δVO(ω) with Equation 55. Performing all these substitutions and after some rearranging, we obtain an expression for IN0(ω) in terms of IN(ω) which is:
IN0(ω)=IN(ω){1+(gm+Gm)Z001+gm(Z1+Z00)-(gm+Gm)IHVBET(1+gmZ1)Z001+gm(Z1+Z00)[G1+(G1+GD1+C1)(G2+GD2+C2)(GD1+C1)]}(59)


The output noise voltage due to the readout and electrical-thermal feedback circuit is readily obtained by combining Equations 55 and 59 to obtain:
δVO(ω)=IN0(ω){1+gmZ1+(2gm+Gm)Z00(1+gmZ1)Z00-(gm+Gm)IHVBET[G1+(G1+GD1+C1)(G2+GD2+C2)(GD1+C1)]}(60)


There are two terms in the denominator that influence the output noise voltage: an electrical feedback term and a thermal feedback term. The value of ∂VBE/∂T≅−2.3 MV/K is negative thereby removing the negative sign from the thermal term in the denominator. The issue is how large is the denominator in Equation 60, since the denominator determines how much the noise current gets attenuated by electrical and thermal feedback effects. The amount of attenuation is estimated by recognizing that Z1≅Z00 and 10gM≈GM, and that the thermal term is much smaller than the electrical term in the denominator of Equation 60. Incorporating these, Equation 60 is simplified to:
δVO(ω)=IN0(ω)[1Z1Gmgm+1Z00]IN0(ω)Z1gmGM(61)


It should be noted that the smaller the ratio of gM/GM is the more the noise is attenuated. This feature and the value of impedance Z1 are used to minimize the noise from the readout and electrical-thermal feedback circuit. In our example, the ratio is ten to one, leading to a ten fold reduction in the electronic circuit noise.


The RMS output noise voltage is evaluated by utilizing Equation 61 and the noise power spectral density. A general expression for the noise power spectral density is given as:
2IN0(ω)f=INO2[1+Bf](62)


The noise power spectral density includes white noise and 1/f noise. The white noise power spectral density amplitude is given by a constant [IN0]2 and the 1/f noise corner frequency is represented by the constant B. For bipolar transistors, such as the transistor 42 shown in FIG. 9, the value of B is estimated to be about 1.0 KHz and could be as low as 100 Hz. The expression for the impedance Z1 corresponds to a parallel combination of a resistance R10 and capacitance C10, and is given as Z1=R10/(1+jωR10C10). Combining all these terms, the equation for the RMS value for the noise voltage is given by:
δVO(RMS)=gmGmIN0R10[12π0w1+R102C102ω2]+[12πω1Bωω(1+R102C102ω2)](63)


The absolute value squared is used for the impedance Z1 because the calculation deals with RMS value of the noise. Additionally, the 1/f noise term is integrated not from zero do avoid divergence. Instead we selected a radial frequency ω1 which is connected to system calibration. Performing the integration on Equation 63 we obtain a closed form value for the electronic noise and it is given as:
δVO(RMS)=gmGmIN0R1014R10C10-BπLn[ω1R10C10](64)


The value of the RMS circuit noise voltage will be compared against the value of the noise voltages from thermal sources. Ideally, we should minimize the circuit voltage to achieve optimum performance.


Total Noise Voltage at MM Ultra Sensitive Silicon Sensor


The total noise at the output of the bolometer pixel 9 (FIG. 9) is the RMS sum of the results given in Equations 35, 41, 46, 52 and 64. Combining all these Equations, the expression for the total RMS noise voltage at the pixel's output is given by:
δVO(RMS)G2IH[(GAEGD1)2δTSS2+(kTHB2C1)+(kTD2C1)+(kTIN2C2)+(14R10C10-BπLn[ω1R10C10])(IN0R10gmGmIHG2)2]1/2(65)


The expression for the total RMS voltage noise includes contributions from: the scene, the heat bath 14, the detector 10, the intermediate stage 16, and the readout electronics including the bipolar transistor 18.


Several things are evident from Equation 65. Similar to the signal (see Equation 33), the noise from the scene signal (represented by the first term in the square brackets in Equation 65) is attenuated by GAE/GD≈1/30. This attenuation makes all the other noise sources more significant and degrades sensitivity. The second term in the square brackets represents the noise from the heat bath 14, and can be reduced by making THB of the heat bath less than TS. of the scene. The third term in the square brackets represents the noise from the detector 10 and the fourth term represent the noise term from the intermediate stage 16. The noise from the intermediate stage 16 can be minimized by making C1<<C2, while the thermal electrical feedback insures that TD≈TIN. The last term represents the electronic readout noise. For best performance, the electronic noise should be less than the thermal noise terms associated with the MM USSS. Specifically, the terms in the square brackets in Equation 65, given by (KTD2/C1), that is approximately equal to (KTHB2/C1), since THB≈TD. The value of this term can be readily estimated by recognizing that TD≈300K. The detector's heat capacity C1 is estimated to be equal C1≅1.56×10−11 J/K, corresponding to the heat capacity of a 5 μm diameter silicon membrane 0.5 μm thick, and K=1.38×10−23J/K. Combining all these terms, the value calculated for (KTD2/C1)≅8×10−8 K2. The ultimate sensitivity is achieved when the leading term in the square brackets is larger than all the other terms. Given that the ration GAE/GD11/30, we conclude that the sensor is limited by the RMS sum of its own thermal fluctuations {second third an forth terms in the square bracket of Equation 65} and the value of the electronic readout noise, fifth term in the square brackets of Equation 65. The sensitivity of the MM USSS is evaluated in the next section.


Noise Equivalent Radiometric Temperature of MM USSS


The Noise Equivalent Radiometric Temperature of the MM USSS {NERΔT} represent the minimum temperature the MM USSS can resolve, and it occurs at a unity signals to noise ratio. Mathematically, this is obtained by dividing the noise voltage, given by Equation 65, by the absolute responsivity, given by Equation 33, and after some rearrangements and the approximation that G1<<G2, we obtain:
NERΔTGD1GAE[(GAEGD1)2δTSS2+(kTHB2C1)+(kTD2C1)+(kTIN2C2)+(14R10C10-BπLn[ω1R10C10])(IN0R10gmGmIHG2)2]1/2[1+(ωC1GD1)21+(ωC2G2)2]1/2(66)


The expression for the MM USSS sensitivity is given as a product of three terms: degradation due to thermal loading [G1/GAE], noise from thermal fluctuations and electronic circuits, and a ‘ac’ factor which represents the frequency response of the detector 10 and intermediate stage 16. We will proceed to address each one of these terms in detail.


The first term is the degradation in sensitivity produced by the thermal loading from GD1 versus the conductance between the detector and scene GAE. Since G1/GAE≈30, this represents a significant degradation. Electrical-thermal feedback has reduced this from G1/GAE≈2400 to GD1/GAE≈30. This represents almost a 100-fold improvement over conventional approaches and clearly illustrates the excellent reason for proposing the MM USSS, which is greatly improved sensitivity.


The terms in the square bracket represent all the noise sources. We can neglect the first term because of the large attenuation factor in front [GAE/GD1]2≈1/900. The combination of the second, third, and fourth term in the square bracket is readily evaluated since we know that from before that (KTD2/C1)≅8×10−8 K2. The heat bath 14 and intermediate stage temperatures 16 are approximated to be about the same as the detector 10 [TD≈THB≈TIN] and 10 C1≅C2. Combining the second, third, and fourth term in the square brackets, we obtain an estimate of about 2×10−7 K2. It should be noted that these three terms by themselves limit the sensitivity to more that 0.013 K.


Unfortunately, this excellent performance is degraded by the electronic circuit noise, given by the fifth term in the square brackets of Equation 66. The degradation is readily estimated by substituting numerical values. By design, R10≈108, C10≈1PF, GM/GM≈0.1, IH/G2≈10, B≈1 KHz and the white noise power spectral density of the bipolar amplifier 18 is [IN0]2(8/3)EIH and estimated as equal to 4.3×10−25. Combining all these, the electronic circuit noise term becomes:
ElectronicNoise=4.2×10-9(2.5×103-103πLn[10-4ω1])K2(67)


The electronic noise includes white noise (first term) and 1/f noise (second term). The total noise depends on the low frequency operating corner ω1 of the sensor. The 1/f noise term is the larger of the two noise terms and depends on the operating corner ω1. If we assume that calibration is performed once every hour, automatically, then the value of Equation 67 becomes 3.2×10−5 K2. This is much larger than the sum of all the detector's thermal noise term of 2×10−7 K2. Inserting the numerical results from Equation 67 into Equation 66 we obtain an estimate for the radiometric temperature resolution and it is 0.2 K. This is represents a prediction of excellent performance for a MM USSS.


From the analyses presented above and the embodiment of the invention disclosed herein, it indicates that the present invention is particularly adapted for passive MM wave imaging. Passive millimeter wave imaging offers several important features including seeing through clothing, through clouds, and during rain. The former characteristic offers application for home defense for remote weapons and explosive detection. The latter characteristic offers improved visibility for military platforms deployed over land, in the air and at sea.


Furthermore, the sensor when made with a monolithic design, on a single silicon wafer, obviates the need of any microwave mixers. Such a simplification in circuitry will directly lead to a significant reduction in cost of fabricating millimeter wave imagers.


Having thus shown and described what is at present considered to be the preferred embodiments of USSS pixel invention, it should be noted that all modifications, changes and alterations coming within the spirit and scope of the invention as set forth in the appended claims are also meant to be included.

Claims
  • 1. An electromagnetic radiation sensor assembly, comprising: a heat bath; an antenna element for receiving radiant electromagnetic energy; a thermally responsive absorber element coupled to the antenna element and including means for absorbing and detecting radiant electromagnetic energy received by said antenna element; an intermediate stage for thermally isolating the absorber element from the heat bath, said intermediate stage including a first and a second thermal isolation member each having a predetermined thermal conductance interconnecting the absorber element to the intermediate stage and the intermediate stage to the heat bath, the first thermal isolation member being located between the absorber element and the intermediate stage and the second thermal isolation member being located between the intermediate stage and the heat bath; an electro-thermal feedback circuit incorporated into the intermediate stage for reducing the thermal conductivity between the absorber element and the heat bath by causing the temperature of the intermediate stage to converge to the temperature of the absorber element when detecting electromagnetic radiation, thus effectively causing the thermal conductance of the first thermal isolation member to attain a minimum conductance value and thereby improve the sensitivity of the radiation sensor towards the radiation limit; and wherein the electro-thermal feedback circuit includes a heat generating amplifier including a bipolar transistor integrated with the intermediate stage and means for detecting the temperature difference between the absorber element and the intermediate stage and generating an output voltage signal dependent on the received electromagnetic radiation to control the power generated by the amplifier, wherein the heat generated by the transistor included in the amplifier itself directly heats the intermediate stage in response to said temperature difference signal so as to equality the temperature between the absorber element and the intermediate stage.
  • 2. A sensor assembly according to claim 1 wherein said sensor assembly comprises a two-tier device and wherein said antenna element, said absorber element and said intermediate stage comprises substantially co-planar elements located above the heat bath.
  • 3. A sensor assembly according to claim 1 wherein said antenna element is located on an upper outer surface of said heat bath.
  • 4. A sensor assembly according to claim 1 wherein the assembly comprises an x-y sensor assembly including x-y address readout circuits, and wherein said heat bath, said antenna element, said absorber element and said intermediate stage form a single pixel addressed by the x-y address readout circuits.
  • 5. A sensor assembly according to claim 1 wherein the spectral response of at least one of the elements including said absorber element and said antenna element is adjusted to operate in a predetermined region of the electromagnetic spectrum, including at least the Infrared region of the electromagnetic spectrum.
  • 6. A sensor assembly according to claim 4 wherein said predetermined region also includes millimeter wave region of the electromagnetic spectrum.
  • 7. A sensor assembly according to claim 4 wherein said absorber element comprises a bolometer.
  • 8. A sensor assembly according to claim 4 wherein said absorber element includes resistor means and temperature sensor means, wherein said resistor means is ac coupled to the antenna to receive and absorb the electromagnetic energy, and said temperature sensor means is thermally coupled to the resistor means to monitor its temperature.
  • 9. A sensor assembly according to claim 4 wherein said pixel is fabricated in silicon.
  • 10. A sensor assembly according to claim 4 wherein a plurality of said pixels are included in an array of pixels.
  • 11. A sensor assembly according to claim 2 wherein said intermediate stage includes a support member and, wherein said support member and said isolation members form a bridge for positioning the absorber element above the means providing a heat bath.
  • 12. A sensor assembly according to claim 11 wherein said heat bath includes a substrate and an upper body portion on which the antenna element is mounted, said upper body portion including a cavity over which the intermediate stage and the absorber element are located.
  • 13. A sensor assembly according to claim 2 wherein said amplifier including a bipolar transistor comprises a differential amplifier and wherein said means for detecting the temperature difference includes first and second diodes for respectively sensing the temperature difference between said absorber element and said intermediate stage.
  • 14. A sensor assembly according to claim 12 wherein the first and second diodes are connected in back-to-back circuit relationship and to the amplifier inputs.
  • 15. A sensor assembly according to claim 3 wherein said intermediate stage includes a centralized opening therein and wherein said absorber element is located in said opening,
  • 16. An electromagnetic radiation sensor assembly, comprising: an array of sensor pixels, each of said pixels including, a heat sink in the form of a heat bath member, an antenna element for receiving radiant electromagnetic energy mounted on the heat bath member, a thermally sensitive detector element coupled to the antenna element for detecting the radiant electromagnetic energy, an intermediate stage located between the detector element and the heat bath member, and a support structure for the intermediate stage comprising a first thermal isolation member having a predetermined thermal and electrical conductance connecting the detector element to the intermediate stage and a second thermal isolation member having a predetermined thermal and electrical conductance connecting the intermediate stage to the common heat bath member; an electro-thermal feedback circuit in the intermediate stage for reducing the thermal conductivity between the detector element and the heat bath member by causing the temperature of the intermediate stage to converge to the temperature of the detector element in response to absorbed electromagnetic radiation, effectively causing the thermal conductance of the first thermal isolation member to attain a minimum conductance value and thereby improve thermal isolation and thus the sensitivity of the sensor element toward the radiation limit; and, wherein the electro-thermal feedback circuit includes a heat generating amplifier, including a bipolar transistor, integrated with the intermediate stage as well as means for detecting the temperature difference between the detector element and the intermediate stage and generating a temperature difference signal for controlling the solid bipolar transistor and the heat generated thereby; and, wherein the heat generated by the bipolar transistor itself directly heats the intermediate stage in response to said temperature difference signal so as to converge the temperature of the intermediate stage to the temperature of the detector element.
  • 17. An electromagnetic assembly according to claim 16 wherein the antenna element, the detector element, the intermediate stage are substantially coplanar in a two tier assembly with the heat bath.
  • 18. A sensor assembly according to claim 16 wherein said detector element comprises a bolometer.
  • 19. A sensor assembly according to claim 16 wherein the spectral response of at least one of the elements including the detector element and the antenna element is adjusted to operate in a predetermined region of the electromagnetic spectrum.
  • 20. A sensor assembly according to claim 18 wherein the predetermined region includes the infrared and/or millimeter wave region of the electromagnetic spectrum.
  • 21. An electromagnetic radiation sensor assembly, comprising: heat bath means; antenna means located on an outer surface of the heat bath means for receiving electromagnetic radiation; heat absorber means for detecting electromagnetic radiation received by the antenna means; thermal isolation means located between the intermediate stage and the heat bath means and the heat absorber means for thermally isolating the heat absorber means from the heat bath means; first means having a predetermined thermal and electrical conductance for connecting the heat absorber means to the thermal isolation means, and second means having a predetermined thermal and electrical conductance for connecting the thermal isolation means to the heat bath means; and, electro-thermal feedback circuit means incorporated into the thermal isolation means for reducing the thermal conductivity between the heat absorber means and the heat bath means by causing the temperature of the thermal isolation means to converge to the temperature of the heat absorber means when detecting electromagnetic radiation, effectively causing the thermal conductance of the first means for connecting to attain a minimum conductance value and thereby improve the sensitivity of the sensor assembly toward the radiation limit; wherein the electro-thermal feedback circuit means includes heat generating bipolar transistor amplifier means integrated with the thermal isolation means, and means for detecting the temperature difference between the heat absorber means and the thermal isolation means and generating a temperature difference signal for controlling the power delivered by the bipolar transistor amplifier to the intermediate stage; and, wherein the heat generated by the bipolar transistor amplifier means directly heats the thermal isolation means in response to said temperature difference signal so as to equalize the temperature between the heat absorber means and the intermediate stage.
  • 22. A sensor assembly according to claim 21 wherein said antenna means, said heat absorber means, and said thermal isolation means form a two-tier sensor assembly.