The invention relates to determination of properties of formations surrounding an earth borehole and, more particularly, to a method for determining properties including the leak-off rate of a mudcake, the perturbing effect of drilling fluid leak-off, and the undisturbed virgin formation pressure.
A serious difficulty of formation pressure determination during drilling operations is related to the pressure build-up around a wellbore exposed to overbalanced pressure and subject to filtrate leak-off called supercharging. This pressure build-up is accompanied by filter cake deposition and growth externally, at the sand face, and internally due to the mud filtrate invasion. Thus, the filter cake hydraulic conductivity changes with time, affecting the pressure drop across it and therefore the pressure behind it, at the sand face. This makes it difficult to predict the evolution of the pressure profile with time, even if the history of local wellbore pressure variation has been recorded.
Existing formation pressure measurements, made with so-called formation testing tools which probe the formations, often read high compared to the actual reservoir pressure far from the borehole, due to the supercharging effect. There are currently no known commercially viable techniques for the determination of the formation pressure in relatively low permeability reservoirs (below approximately 1 mD/cp) during drilling operations which adequately account for supercharging. The main difficulties are related to (1) the poor filter cake property, (2) the long actual time of wellbore exposure to overbalanced pressure, and (3) the practical time constraints, which require the pressure measurements to be carried out during a rather short time compared to the time of pressure build-up around a wellbore. These constraints make it difficult, if not impossible, to sense the far field formation pressure, at the boundary of the pressure build-up zone, with the usual transient pressure testing techniques, because of the slow pressure wave propagation inherent in low permeability formations.
Accordingly, while existing tools and techniques can often work well in relatively high permeability formations, where supercharging easily dissipates, e.g. during tool setting, there is a need for a technique that can be successfully employed in relatively low permeability formations. It is further desirable to have a technique that is applicable to formations of wide ranging permeability, irrespective of the origin of the supercharging. There is also a need for accurate determination of filtrate leak-off parameters. It is among the objects of the present invention to address these needs.
In accordance with an embodiment of the invention, a method is set forth for determining the virgin formation pressure at a particular depth region of earth formations surrounding a borehole drilled using drilling mud, and on which a mudcake has formed, comprising the following steps: keeping track of the time since cessation of drilling at said depth region; deriving formation permeability at said depth region; causing wellbore pressure to vary periodically in time and determining, at said depth region, the periodic component and the non-periodic component of pressure measured in the formations adjacent the mudcake; determining, using said time, said periodic component and said permeability, the formation pressure diffusivity and transmissibility and an estimate of the size of the pressure build-up zone around the wellbore at said depth region of the formations; determining, using said time, said formation pressure diffusivity and transmissibility, and said non-periodic component, the leak-off rate of the mudcake at said depth region; determining, using said leak-off rate, the pressure gradient in the formations adjacent the mudcake at said depth region; and extrapolating, using said pressure gradient and said size of the pressure build-up zone, to determine the virgin formation pressure.
In accordance with a further embodiment of the invention, a method is set forth for determining the leak-off rate of a mudcake formed, at a particular depth region, on a borehole drilled in formations using drilling mud, and on which a mudcake has formed, comprising the following steps: deriving formation permeability at the depth region; causing wellbore pressure to vary periodically in time, and measuring, at the depth region, the time varying pressure in the borehole and the time varying pressure in the formations adjacent the mudcake; determining, at the depth region, an estimate of the flow resistance of the mudcake from the derived permeability and components of the measured pressure in the borehole and the measured pressure in the formations adjacent the mudcake; and determining, at the depth region, the leak-off rate of the mudcake from the estimated flow resistance and the measured pressure in the borehole and the measured pressure in the formations adjacent the mudcake. The virgin reservoir pressure can then be obtained by: determining, at the depth region, the pressure excess in the formations adjacent the mudcake from said derived permeability, said leak-off rate, and said time since cessation of drilling; and determining, at said depth region, the virgin reservoir pressure from said measured pressure in the formations adjacent the mudcake and said pressure excess in the formations.
Further features and advantages of the invention will become more readily apparent from the following detailed description when taken in conjunction with the accompanying drawings.
The logging device or tool 100 has an elongated body 105 which encloses the downhole portion of the device controls, chambers, measurement means, etc. Reference can be made, for example, U.S. Pat. Nos. 3,934,468, and 4,860,581, which describe devices of suitable general type. One or more arms 123 can be mounted on pistons 125 which extend, e.g. under control from the surface, to set the tool. The logging device includes one or more probe modules that include a probe assembly 210 having a probe that is outwardly displaced into contact with the borehole wall, piercing the mudcake 35 and communicating with the formations. The equipment and methods for taking individual hydrostatic pressure measurements and/or probe pressure measurements are well known in the art, and the logging device 100 is provided with these known capabilities. Referring to
Embodiments of the present invention can also be practiced using measurement-while-drilling (“MWD”) equipment (which includes measuring while tripping).
The pressure build-up around the wellbore in relatively low permeability formations (such as k=10−1 mD) during drilling operations is a slow process, which usually lasts a few days and affects a relatively small neighborhood of the wellbore. The radius of the zone with elevated pressure around the wellbore can be estimated, using dimensional analysis.
Assume that Darcy's law governs the flow in the reservoir
where v is the fluid flow velocity, μ is the fluid viscosity and p is the pore pressure, which has to satisfy the pressure diffusivity equation
where t is the time, B is the bulk modulus of the rock saturated with fluid, φ is the porosity and η is the pressure diffusivity (see G. I Barenblatt, V. M. Entov and V. M. Ryzhik: Theory of Fluid Flows Through Natural Rocks, Dordrecht: Kluwer, 1990).
If the time of exposure of the wellbore to overbalance pressure, te, is known, then the radius of the zone with elevated pressure around it can be estimated as
re≈2√{square root over (ηte)} (3)
Using, for example, the following data: k=10−3−10−1 mD, B=1 GPa, μ=1 cp and φ=0.2, one would obtain η=(5−500)·10−6 m2/s. For the pressure build-up time te=1 day, one finds
re≈1.3−13 m (4)
The depth of investigation by conventional transient pressure testing, ri, also can be estimated, using the same formula (3). For example, if the investigation times are ti=2 hours, 20 min and 2 min, then the ratio ri/re can be respectively estimated as
ri/re=√{square root over (ti/te)}≈0.29, 0.12, 0.04 (5)
This means that only first 29%, 12%, and 4%, respectively, of the thickness of the pressure build-up zone can be sensed by the methods of transient pressure testing.
The analysis of pressure build-up around the wellbore during drilling requires coupled consideration of the pressure wave propagation and the filter cake growth, induced by mud filtrate leak-off and usually restricted by the mud circulation inside the wellbore. If the overbalance pressure applied during drilling operations does not change dramatically, the transient pressure evolution around the wellbore can be approximated by the quasi-steady pressure behavior
where p0 is the original formation pressure, psf(t) is the pressure at the sand face, rw is the wellbore radius and re(t) is the radius of zone around the wellbore with build-up pressure. The schematic of the pore pressure profile is shown in
If the filter cake permeability is small compared to that of the formation, the sand face pressure, psf, falls quickly to the initial formation pressure, p0. If, however, the formation permeability is small and therefore the leak-off through the sand face is restricted, the filter cake is not built efficiently and the exposure of the formation to the overbalanced pressure can continue indefinitely.
The unknown functions, psf(t) and re(t), can be found from the pressure diffusivity equation (2) coupled with the model of the filter cake growth at the sand face. This analysis can be carried out for a simple model of the filter cake growth, based on the following assumptions: the porosity and permeability of filter cake are constant; the volumetric concentration of solids in the mud, filling the wellbore, is constant; the filtrate invading into the formation is fully miscible with the reservoir fluid; the filtrate viscosity is equal to that of reservoir fluid; and both spurt loss and internal filter cake formation are neglected. It is also assumed in this analysis that the filter cake permeability is much smaller than the reservoir permeability and the filter cake thickness, growing with time, is small compared to the wellbore radius. Under these assumptions, the flow through the filter cake can be considered as quasi-steady and one-dimensional at any time and therefore the pressure variation across the filter cake is linear as shown in
The sand-face pressure, psf(t), is affected by a lot of factors, including the reservoir hydraulic conductivity, the leak-off rate and the rate of mud circulation. It also depends on the filter cake hydraulic resistance, which varies with time. Despite this complexity, the boundary of the pressure perturbation zone, re(t), plotted in appropriate dimensionless variables, is found to not practically depend on the filter cake growth dynamics and can be approximated by a universal function Ze(T), shown in
Since the time of wellbore exposure to overbalance pressure, te, is usually known, the only parameter, which is needed for the estimation of the radius of zone with perturbed pressure, re(te), is the pressure diffusivity, η, which is involved in the definition of the dimensionless time T.
Assume that η has been found somehow and therefore the boundary re(te)
Then, one has to measure the pore pressure at the sand face, psf(te), and at an intermediate point r=rm inside the zone rw<r<re(te) in order to find the formation pressure
The sand-face pressure psf(te) can be measured by currently available wireline testing tools and therefore, in order to obtain the formation pressure, p0, one has to determine the two parameters only—the pressure diffusivity, η, and the pressure at some distance from the wellbore, pm, or alternatively the pressure gradient at the sand face
Thus, if the formation transmissibility, kh/μ, which involves the interval thickness h, is known, the determination of the formation pressure, p0, is equivalent to the determination of the quasi-steady leak-off rate, qL(te), at the end of the pressure build-up phase
As shown below, qL, can be determined using pulse-harmonic tests, which can be carried out with appropriately chosen testing frequencies and pumping rates.
In the following analysis of determination of far field formation pressure using pulse-harmonic testing, it is assumed that total testing time is small compared to the pressure build-up time (the time of borehole exposure to pressure overbalance); the pre-test volume is small compared to the total volume produced during testing, and the filter cake is removed during pre-test. For simplicity, variation of the pressure diffusivity and the formation transmissibility versus the distance from the wellbore are ignored.
Consider the situation just before pulse-harmonic testing, i.e. at t=te. The pressure around the wellbore, pe(r)=p(r,te), specifies the initial condition with respect to the testing time τ=t−te. Using the same notation for the pressure, p(r,τ), one has
p(r,0)=pe(r), r≧rw (12)
As mentioned above, the function pe(r) is usually unknown except, its boundary value, pw0=pe(rw), which can be measured or estimated, using conventional formation testing. Using Eq. (6), the initial pressure profile around the wellbore before testing can be expressed as
and the corresponding quasi-steady leak-off rate from the wellbore interval of thickness h is
This leak-off rate, qL, is unknown in advance and its determination would be equivalent to the determination of the two parameters: the radius of the pressure build-up zone, re(te) and the formation pressure, p0.
Using Eq. (14), the initial pressure profile can be represented in the equivalent form
Generally speaking, the parameter φL could be determined, using, for example, the conventional pressure build-up technique, if one could seal instantaneously the sand face of the wellbore interval and monitor the pressure relaxation, pw(τ), behind the sand face with time. Indeed, due to the superposition principle, the pressure response at the sealed sand face to the step-wise variation of the flow rate can be expressed as
Ψw(τ)=pw(τ)−pw0=−φLF0(ητ/rw2) (16)
Here, the function F0(a), where a=ητ/rw2, is given by the well-known solution of the pressure diffusivity equation (see, for example, H. S. Carslaw and J. C. Jaeger: Conduction of Heat in Solids, 2nd Edition, Oxford: Clarendon Press, 1959)
where the Ji and Yi are Bessel functions of the first and second kind, respectively, of order i, i=0, 1, and it is shown in
one could determine the two parameters, φL and η/rw2, by plotting Ψw(τ) versus log τ.
This straightforward approach, which is widely used in the well testing technology (see T. D. Streltsova: Well Testing in Heterogeneous Formations, Exxon Monograph, John Wiley and Sons, 1988), is, however, rather difficult to implement in reality. There are a few reasons for this. First of all, the necessary testing time in low permeability formations is usually extensive. Secondly, the initial leak-off rate in a low permeability formation is typically very small and can be very difficult to measure. The sealing of the sandface and the pressure monitoring is preferably done with great care so as not to disturb the formation and the pressure at the sandface. It is worth noting also that the sealing of the wellbore surface could be replaced by the pressure relaxation procedure, which would prevent the leak-off, but this is not much easier to implement because the detection of a very small leak-off can be even more challenging. Thus, a different type of pressure testing procedure is needed. Pulse-harmonic testing has the advantage of not compromising the accuracy of measurements and the amount of information to be extracted from the data is comparable to that, which maybe extracted by conventional means.
Consider the pressure evolution around the wellbore during pulse-harmonic testing with a production rate qw(τ), having a period {overscore (T)}. Using the superposition principle, one can represent the production rate perturbation during testing, q(τ)=qw(τ)+qL, as a sum of its periodic component with zero average rate, qp(τ), and the constant average rate, qa, i.e.
q(τ)=qp(τ)+qa, qa={overscore (q)}w+qL, qp(τ)=qw(τ)−{overscore (q)}w (19)
where
The unknown leak-off rate, qL, has been added to the production rate qw(τ) to compensate for the initial non-uniform pressure profile (15) around the wellbore. The advantage of this testing procedure is that the periodic part, qp(τ), can be tuned for different depths of investigation, R≈2√{square root over (πη{overscore (T)})}, by changing the angular frequency ω=2π/{overscore (T)} (see Stretsolva, supra). The testing time is comparable with the period {overscore (T)} and is usually much shorter than the duration of a pressure build-up after shut-in. At the same time, the average rate, {overscore (q)}w, should not depend too much on the characteristics of the hardware (pumps, pressure gauges, flow meters). It can be tuned by choosing, for example, appropriate amplitudes, q0, and durations, t0, of production pulses and the ratio t0/{overscore (T)} (
The other advantage of this superposition is that the periodic component, qp(τ), does not involve the unknown initial leak-off rate, qL, and the extraction of the pressure response to the periodic rate qp(τ), from the measured pressure variation at the wellbore, Ψw(τ), is a standard task in the practice of pulse-harmonic testing (see Streltsova, supra). Processing the pressure response to the periodic component, allows one to determine the pressure diffusivity, η, and the formation transmissibility, kh/μ. This reduces the number of unknown parameters in the presentation of the initial pressure profile before testing, determined by Eqs. (13) and (8), to only one—the formation pressure, p0.
The determination of p0 requires the processing of the wellbore pressure response to the non-periodic component of the production rate, which is represented by the average constant rate, qa. Using the superposition principle, this response can be expressed similarly to (16) as
Here, Ψa(τ) is the measured pressure response minus the periodic component; the parameter {overscore (φ)}w is already known, and the parameter φL is still unknown.
The function F0(a) is defined by (17) and shown in
Thus, the last term in the right-hand side of Eq. (22), which formally depends on the testing time τ, has actually to be constant. This term can be estimated, using the pressure measurements in the wellbore, Ψa(τ), and the function F0(a), representing the dimensionless reservoir pressure response to an average step-wise production rate.
After the determination of the parameter φL, the desired formation pressure can be estimated as
p0=pw0−φL log[re(te)/rw] (23)
Eq. (22) can be also interpreted as follows. In the absence of the initial pressure build-up and the corresponding leak-off rate, the last term in its right-hand side has to be equal exactly to {overscore (φ)}w. This means that the difference between the two terms at qL≠0 represents the effect of the “boundary condition” at the virtual moving boundary, corresponding to the pressure wave, propagating into the formation, as shown in
In the following example, consider the multiple-pulse testing procedure, illustrated in
{overscore (q)}w=q0(t0/{overscore (T)}) (24)
Using the superposition principle, the pressure response to the first production pulse at the wellbore can be represented as
Ψw(τ)=−{overscore (φ)}w[F0(a)−θ(τ−t0)F0(a1)] (25)
where θ(τ) is the Heaviside unit step function and
Using the measurements of the pressure perturbation at the first shut-in (the point A in
After η has been found, the formation transmissibility can be calculated as
Now, the pressure response at the wellbore to the non-periodic rate, Ψa(τ), has to be extracted from the measured pressure curve 0ABCD . . . as shown in
where the function Ze(T) is shown in
The graphical interpretation in
The fluid volume, located between the pump and the wellbore surface (or sand face), which is known also as a storage volume, can distort the production pulses created at the pump. As a result of this distortion, the boundary condition at the wellbore surface does not match exactly the production schedule, generated by the pump, and therefore the pressure response is different from the obtained solution. This phenomenon, known as a wellbore (or tool) storage effect, can be important if the storage volume is large compared to the total production volume per testing cycle. Indeed, the storage volume is decompressed during production and pressurized during injection cycles, damping the rate variation, induced by the pump, and therefore smoothing the formation response to it. If the compressibility of the fluid in the storage volume is constant, the storage effect can be investigated, using the Laplace transformation technique (see Barenblatt et al., supra, and Carslaw et al., supra).
The fundamental solution for the step-wise production rate with amplitude q0 and zero initial conditions is given (Carslaw et al., supra) by the formulae
u(z)=γzJ0(z)−J1(z), v(z)=γzY0(z)−Y1(z) (32)
It involves the additional dimensionless parameter γ, which is determined as
which is the ratio of the two characteristic times, τS and τF, corresponding to the storage volume and the formation respectively. Here, VS is the storage volume and c0 is the fluid compressibility, which correlates the variation of the storage volume, ΔVS, with the pressure variation, Δp, as ΔVS=−c0VSΔP. The solution (31)–(32) becomes identical to (17) at γ=0. The function (2π)−1FS(a) versus log10(a) for γ−1=0.5, 1, 2, 4 and ∞ is shown in
It will be understood that the described technique can be expanded to take into account the variation of the formation properties, i.e. the pressure diffusivity and transmissibility, with the distance from the wellbore due to invasion of mud filtrate into the formation during drilling. Pulse-harmonic testing with different frequencies can be used to discriminate the responses of the damaged zone and the undamaged formation. The design of the testing procedure in such a case would require some a priori information (at least, an order of magnitude estimate) about the formation transmissibility and diffusivity. If they vary significantly with distance from the wellbore, the interpretation of the pressure response to a non-periodic component of the production rate would need to be modified, and a longer testing time would generally be necessary.
For the pumping/injection mode of
For testing in a production mode, as illustrated in
A further embodiment of the invention will next be described, this embodiment including a technique for estimating the parameters of the mudcake which control filtrate leak-off rate, and for using this estimate in turn to estimate the true reservoir pressure from the measured sandface value. A flow diagram of the steps for practicing this embodiment is shown in
The time post-drilling is kept track of (block 1103). As represented by block 1105, a formation pressure measurement tool is deployed in the well, and set on the formation of interest. An estimate of the formation permeability is made (block 1110). This can be done using standard means; for example, interpretation of pre-test pressure transients. This is combined with an estimate of the formation total compressibility, to obtain an estimate of the formation pressure diffusivity (block 1115). The wellbore pressure is caused to vary periodically in time (block 1125) with significant frequency content in an appropriate frequency range, as discussed above, and treated further below. The time-varying pressures measured by the formation probe pressure sensor, and a pressure sensor in the wellbore (
The estimated flow resistance of the mudcake is then combined with the measured wellbore and sandface pressures to estimate the filtrate leak-off rate (block 1150). Then, as represented by the block 1160, the filtrate leak-off rate is combined with the estimated formation permeability and the time of exposure of the formation post-drilling, to estimate the pressure excess at the sandface due to leak-off (i.e. supercharging). This pressure excess is subtracted from the measured pressure, to yield an estimate of the true reservoir pressure uncontaminated by supercharging (block 1170).
Further detail of the routine for this embodiment will next be described. Regarding step 1125, once the tool's probe is set and in pressure communication with the formation, steps are taken to induce modest amplitude, time periodic, absolute pressure variations within the wellbore, so as to create (a) measurable pressure disturbance within the wellbore at the tool, and (b) a measurable response to this disturbance, as seen by the pressure sensor in communication with the formation through the probe (e.g.
The wellbore pressure can be written as pw(t)={overscore (p)}w+({circumflex over (p)}w(ω)eiωt), where {overscore (p)}w denotes the (constant) background wellbore pressure about which the fluctuations take place, (.) indicate the “real part” of argument, {circumflex over (p)}w denotes the amplitude of the oscillation, ω is the frequency. Mechanisms for generation of pressure variations within the formation include the response to changing filtrate loss rates through the mudcake (although other processes could contribute, e.g. elastic deformations of the rock or deformation of the mudcake itself). The frequency of the wellbore pressure fluctuations should be chosen so that the measured attenuation of pressure fluctuations across the mudcake is adequately sensitive to the flow resistance of the mudcake. Computed pressure responses are shown in
Regarding interpretation of attenuation of pressure fluctuations for the mudcake skin, the complex amplitude of axisymmetrical time harmonic pressure fluctuations within the formation, having angular frequency ω, satisfies
where actual pressures are given by p(r,t)=({circumflex over (p)}(r,ω)eiωt), η=k/φμct, where k is the formation permeability, φ the formation porosity, μ the viscosity of the fluid in the pore space and ct the compressibility of the fluid-solid system (formation saturated with fluid). Pressure fluctuations decay at great distances, so {circumflex over (p)}(r,ω)→0 as r→∞. At the wellbore wall, the mudcake is modeled as an infinitesimally thin “skin”, across which there is a pressure loss proportional to the instantaneous flow rate, so that
where the non-dimensional parameter S is the standard skin factor familiar in well testing. It can be shown that
where the K's are modified Bessel functions, and the branch of the square root is chosen so as to ensure decay of pressure perturbations at large distances.
As a further refinement, the drilling fluid circulation rate and/or long-time average wellbore pressure can also be varied. Changes in circulation rate will cause erosion (or further growth) of the mudcake, and changes in filtration pressure will cause the cake to compact (or expand slightly). The cake skin at each circulation rate or overpressure can be estimated using the method just outlined, and by this means a table of values of S versus circulation rate (denoted as {dot over (γ)}) and/or filtration pressure (pw−p(rw,t), denoted as Δp) can be created. The values stored in this table can be used in the step of block 1150 (treated further below), so that the value of S corresponding to the current circulation conditions is used when evaluating the leak-off rate. Interpolation between measured values may be used.
Regarding the step of block 1150, the instantaneous pressure drop across the mudcake is related to the sandface pressure gradient by
and using Darcy's law at the sandface,
to relate the sandface pressure gradient to the filtrate leak-off flux, q, one obtains
Using this expression, under the assumptions that (a) the fluid loss can be adequately described by the skin parameter S estimated above, and (b) sufficient data has been collected in the previous steps to permit extrapolation and interpolation to estimate S over the range of wellbore flow rates and pressures occurring between first exposure of the formation and the formation pressure measurement (or have a mechanistic model to link values of S measured at one set of wellbore conditions to those pertaining at another), the filtrate loss rate q(t) can be estimated given the measured time histories of wellbore and sandface pressures, pw(t) and p(rw,t), respectively and information on the drilling fluid circulation rate.
Regarding steps 1160 and 1170, the sandface pressure is related to the fluid leak-off rate through the familiar convolution integral
where t0 denotes the time at which the formation was first drilled, p∞ is the reservoir pressure at great distances from the well, G is the formation impulse response which contains as parameters the formation permeability (k) and pressure diffusivity (η), and q(t1) is the filtrate leak-off rate time history estimated as described above. The functional form of G is well known in the art.
By comparing the predicted sandface pressure, given by the previous equation, with the sandface pressures actually measured, p∞ can be estimated. Stated another way, the quantity
can be taken as an estimate of the overpressure due to supercharging, and subtracted from measured pressures so as to give an estimate of the true formation pressure. It will be understood that this embodiment relies on an indirect estimation of overpressures from filtercake resistance which affects the accuracy of the technique. The interpretation model assumes that that mudcake is thin, and behaves like a simple additional resistance to fluid flow between wellbore and formation. The technique may be modified to take account of the finite thickness of the cake, unsteady pressure diffusion within the cake itself, and/or interactions between the hydraulic properties of the cake and the changing wellbore pressure.
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be devised which do not depart from the scope of the invention as disclosed herein. For example, embodiments of the invention may be easily adapted and used to perform specific formation sampling or testing operations without departing from the spirit of the invention. Accordingly, the scope of the invention should be limited only by the attached claims.
Number | Name | Date | Kind |
---|---|---|---|
3934468 | Brieger | Jan 1976 | A |
4597290 | Bourdet et al. | Jul 1986 | A |
4833914 | Rasmus | May 1989 | A |
4860581 | Zimmerman et al. | Aug 1989 | A |
5144589 | Hardage | Sep 1992 | A |
5205164 | Steiger et al. | Apr 1993 | A |
5226310 | Steiger | Jul 1993 | A |
5282384 | Holbrook | Feb 1994 | A |
5285692 | Steiger et al. | Feb 1994 | A |
5415030 | Jogi et al. | May 1995 | A |
5602334 | Proett et al. | Feb 1997 | A |
5644076 | Proett et al. | Jul 1997 | A |
5672819 | Chin et al. | Sep 1997 | A |
5789669 | Flaum | Aug 1998 | A |
6157893 | Berger et al. | Dec 2000 | A |
6236620 | Schultz et al. | May 2001 | B1 |
6427785 | Ward | Aug 2002 | B1 |
6904365 | Bratton et al. | Jun 2005 | B1 |
6907797 | DiFoggio | Jun 2005 | B1 |
20040144533 | Zazovsky | Jul 2004 | A1 |
20040176911 | Bratton et al. | Sep 2004 | A1 |
Number | Date | Country | |
---|---|---|---|
20050171699 A1 | Aug 2005 | US |