1. Field of the Invention
The present invention relates to geophones, devices for sensing vibrations in earth formations. The invention may be applicable to other types of vibration transducers, either in sensing or transmitting operation.
In seismic exploration, the vibrations in the earth resulting from a source of seismic energy are sensed at discrete locations by sensors and the output of the sensors used to determine the nature of the underground formations. The source of seismic energy can be natural, such as earthquakes and other tectonic activity, subsidence, volcanic activity or the like, or man-made such as acoustic noise from surface or underground operations, or from deliberate operation of seismic sources at the surface or underground. Sensors fall into two main categories; hydrophones which sense the pressure field resulting from a seismic source, or geophones which sense vibration arising from a seismic source.
When the earth moves due to the seismic energy propagating either directly from the source or via an underground reflector, the geophone, which can be located at the earth's surface or on the wall of a borehole which penetrates the earth, moves in the direction of propagation of the energy. If the axis of the geophone is aligned with the direction of motion, however, the moving coils mounted on the springs inside the geophone stay in the same position causing relative motion of the coils with respect to the housing. When the coils move in the magnetic field, a voltage is induced in the coils which can be output as a signal. The response of a geophone is frequency dependent.
In order to ensure proper working operation of a geophone, it is preferable to have the geophone calibrated periodically or before each use. Typically, geophone manufacturers and vendors do not perform any calibrations on their geophone units before the units are sold to customers. Rather the manufacturers provide assurances that the specifications of geophone units are within specified tolerance ranges at a specific temperature such as room temperature. However, such tolerance guarantees are not a substitute for proper calibration of the geophone units. Consequently, many purchasers of geophone units perform their own calibration tests on the purchased geophone units before deploying such units in the field.
However, conventional geophone calibration tests are often inadequate for assuring the desired precision of the geophone measurements typically demanded for many of today's seismic exploration activities. Accordingly, it will be appreciated that there exists a desire to improve upon conventional geophone calibration tests in order to improve the accuracy of seismic exploration measurements.
Different embodiments of the present invention are directed to various methods, systems, and computer program products for calculating response parameters of a geophone configured for use in seismic exploration activities. At least one calibration test is performed on the geophone to determine values for a first portion of response parameters associated with the geophone. The first portion of response parameters may include, for example, open circuit sensitivity, damping factor, natural frequency, etc. Using information relating to the first portion of response parameters, a moving mass parameter value for the geophone may then be determined. According to one embodiment, the moving mass parameter value represents an amount of moving mass associated with the geophone.
Another aspect of the present invention is directed to a technique for modifying geophone response output information generated by a first geophone configured for use in seismic exploration activities. A transfer function for an ideal response of a second geophone is determined based upon information relating to a portion of response parameters associated with the second geophone. The portion of response parameters may include, for example, open circuit sensitivity, damping factor, natural frequency, etc. The geophone response output information generated by the first geophone may then be modified using the transfer function. According to a specific embodiment, another transfer function may be determined for the first geophone based upon information relating to a portion of response parameters associated with the first geophone. The geophone response output information generated by the first geophone may then be modified using the first and/or second transfer functions.
Yet another aspect of the present invention is directed to a technique for processing seismic exploration information generated from seismic exploration activities. A first portion of the seismic information includes geophone response output information generated by at least one geophone. A second portion of the seismic exploration information includes source signal information relating to at least one source signal used in performing the seismic exploration activities. A first portion of response parameter values associated with a first geophone is determined. In one embodiment, the first portion of response parameter values may be determined by performing at least one calibration test procedure on the geophone. Accuracy of the seismic exploration information may then be improved by modifying at least a portion of the seismic exploration information to compensate for one or more of the first portion of response parameter values.
Additional objects, features and advantages of the various aspects of the present invention will become apparent from the following description of its preferred embodiments, which description should be taken in conjunction with the accompanying drawings.
As described in greater detail below, the present invention provides various techniques which may be used to facilitate and improve seismic exploration activities. For example, one aspect of the present invention is directed to a technique for enabling in-situ measurement of geophone response parameters. Another aspect of the present invention is directed to a technique for improving geophone calibration and for improving the accuracy of measurement of geophone response parameters. Yet another aspect of the present invention is directed to a technique for compensating geophone response output data in order to improve the accuracy of such data.
In order to gain a better understanding the various techniques and features described in this application, a brief description of geophone measurement techniques will now be described.
A seismic survey measures seismic waves propagated through the earth to map structural images in the earth. Geophones are often used to detect seismic signals at various locations, such as, for example, down holes, ground surfaces and/or seabeds. An example of a conventional geophone is shown in
As shown in the embodiment of
The geophone response is usually defined by its associated response properties, such as, for example, its natural frequency, damping factor, sensitivity and DC resistance of coil at room temperature. An example of traditional geophone response properties may be expressed by the following equations (1)-(6). For purposes of illustration, it is assumed that the geophone responds to sinusoidal earth accelerations. Thus, for example, the earth accelerations expressed by
α=α sin(ωt), (1)
In the acquisition of seismic data, seismic waves are used to interpret subsurface geological formations. One type of geophysical prospecting technique is generally known as “vibroseis” prospecting or simply vibroseis. Vibroseis employs a seismic vibroseis source used to generate a controlled wavetrain that propagates through the earth or water to be detected by seismic detectors (e.g., geophones).
In seismic acquisitions which utilize a vibrator 812 such as that illustrated in
The cross-correlation unit 912 comparison the unfiltered pilot sweep signal with the geophone filtered sweep signal.
Geophone Response Characteristics and Calibration
Geophone manufacturers typically supply geophones with nominal response properties at room temperature, and provide assurances that the response properties are within specified tolerance ranges. For example, a manufacturer may specify that the tolerance ranges at room temperature may be, for example, +/−5% for natural frequency, open circuit sensitivity, open circuit damping and DC resistance. However, tests performed by the present inventive entity have shown that 5% errors in the geophone response properties can result in amplitude measurement errors of 15% or more.
In order to process seismic signals with sufficient high fidelity to be able to extract precise information, it is preferable to calibrate the geophone prior to use, and to compensate for geophone response properties by adjusting, for example, data produced from the geophone response to take into account geophone calibration and/or response properties.
Traditionally, geophone calibration is accomplished by performing one or more tests on the geophone in order to determine the geophone's response properties, namely natural frequency, damping factor, sensitivity and DC resistance. Typically, the geophone's DC resistance (r) of the moving coil is measured using a multimeter. The natural frequency, damping factor, and sensitivity characteristics of the geophone may be measured using different measurement or testing techniques such as, for example, step calibration test techniques, impulse calibration test techniques, impedance calibration test techniques or dynamic calibration test techniques. The sensitivity characteristics of the geophone may also be measured using a reciprocity calibration test technique. Each of these different measurement techniques is described below.
Step Calibration Test Technique
An example of a step calibration test technique for measuring geophone response properties may be illustrated with reference to
Impulse Calibration Test Technique
An example of an impulse calibration test technique for measuring geophone response properties may be illustrated with reference to
Impedance Calibration Test Technique
An example of an impedance calibration test technique for measuring geophone response properties may be illustrated with reference to
In Equation 7 above, the electric signal applied to the coil is represented by e2. The current which flows into the coil may be determined by e1 and R.
The impedance of a geophone may be expressed as:
Calculation of impedance utilizes at least two measurements at the frequencies ω1 and ω2.
The natural frequency (ω0), damping factor (ζ0) and sensitivity (S0) may be calculated according to:
and where:
It will be appreciated that calculation of the geophone response properties using the above-described impedance calibration test technique relies upon utilizing a known value for the amount of moving mass (m) of the geophone. Typically, this known value for m corresponds to the nominal value of the moving mass which is provided by the manufacturer.
Dynamic Calibration Test Technique
An example of a dynamic calibration test technique for measuring geophone response properties may be illustrated with reference to
According to one embodiment of the dynamic calibration test technique, a calibrated reference sensor 604 and one or more geophones 602 to be calibrated are positioned on top of a shaking device 606, as illustrated, for example, in
It will be appreciated that the relative accuracy of the dynamic calibration test technique depends upon the accuracy of calibration of the reference sensor and the response of the reference sensor. Typically, the reference sensor 604 is calibrated by a third party which is associated with some type of entity for measurement standards.
The embodiment of
According to at least one embodiment, the geophone(s), reference sensor and shaker device may be enclosed in a housing which, for example, may be made with iron, steel, and/or materials which help to prevent magnetic coupling between the shaker and the geophones.
According to a specific implementation of the dynamic calibration test technique, the reference sensor 604 may correspond to a reference geophone in which the moving mass of the reference geophone has been substantially accurately measured and/or determined. Various techniques for accurately measuring a geophone's moving mass are described in greater detail below.
Reciprocity Calibration Test Technique
An example of a reciprocity calibration test technique for measuring geophone response properties may be illustrated with reference to
According to one embodiment, the reciprocity calibration test technique may be used to determine the sensitivity of multiple geophones in situations where no reference sensor is used.
For example, as shown in the embodiment of
In open circuit conditions, the responses output signals of geophones Gb and Gc (namely eab and eac) may be expressed as a function of input signal voltage and geophone impedances as shown below:
Another sinusoidal electric signal is then input into geophone Gb to thereby shake geophone Gc along with block 710 (as illustrated, for example, in
The response of geophone Gc (ebc) may then be expressed by:
The absolute sensitivities of three geophones may be determined by solving the equations below:
The embodiment of
Additional details relating to the reciprocity calibration test technique may be found in the reference “The Reciprocity Calibration of Piezoelectric Accelerometers,” by Mark Harrison, A. O. Sykers, and Paul G. Marcotte, THE JOURNAL OF THE ACCOUSTICAL SOCIETY OF AMERICA, Volume 24, Number 4, July, 1952, herein incorporated by reference in its entirety for all purposes.
A detailed description of various embodiments of the reciprocity calibration test technique for geophone calibration is described in U.S. Pat. No. 5,644,067 to Gabrielson, entitled “APPARATUS AND METHOD FOR CALIBRATION OF SENSING TRANSDUCERS”, the entirety of which is incorporated herein by reference for all purposes.
Other Factors Affecting Geophone Calibration
Research conducted by the present inventive entity has revealed that geophone response measurements are dependent not only upon its internal response properties, but also upon external factors such as, for example, temperature and tilt of the geophone. For example, the DC resistance (r) of the geophone is a function of temperature, and the geophone response is also a function of temperature. More specifically, by considering the electric circuit shown in
Moving Mass Issues
In addition to the above-described factors which may affect geophone response measurements and/or response properties, it will be appreciated that many of the above-described geophone calibration and geophone response property test techniques are dependent upon utilizing known values for various geophone properties in order to determine values for unknown geophone properties. For example, as described previously, at least a portion of the above-described geophone calibration test techniques and geophone response property test techniques rely upon using a pre-known value for the amount of moving mass (m) of the geophone. As described previously with respect to
Because geophone manufacturers typically provide values for nominal geophone response properties, and provide assurances that the response properties are within specified tolerance ranges, it is common practice in the industry, when performing geophone calibration tests, to rely upon the nominal value of the moving mass which is provided by the manufacturer. Moreover, precise calculation of the geophone moving mass value is extremely difficult to ascertain. One reason for this is that the moving mass is comprised of several different (and sensitive) components within the geophone which are typically inaccessible to the user. Another reason is that it is difficult to determine the precise portion of moving suspension spring mass which contributes to the geophone moving mass value.
Moreover, there has conventionally been no need or desire to perform independent measurements of geophone moving mass values since, conventionally, there has been no recognition in the industry of the possibility that errors in geophone moving mass values may significantly contribute to errors in geophone calibration and/or geophone response characteristics. As a result, there has been no motivation to one having ordinary skill in the relevant art to measure the geophone moving mass value to a degree of precision which is greater than that of the nominal value provided by the manufacturer.
Contrary to conventional wisdom, however, the present inventive entity has discovered that errors in the geophones nominal moving mass values, may, in fact, significantly contribute to errors in geophone calibration and/or geophone response characteristics. Accordingly, one technique for improving geophone calibration measurements and/or geophone response compensation techniques is to perform an accurate measurement of the geophone moving mass properties. According to at least one embodiment of the present invention, the amount of moving mass may be measured and used to determine and/or compensate for various geophone response characteristics. In one implementation, the measured amount of moving mass may be used to more accurately determine the geophone response properties (such as, for example, natural frequency, damping factor, sensitivity, etc.) using, for example, one or more of the geophone response property test techniques.
According to a specific embodiment of the present invention, one technique for improving geophone calibration measurements and/or geophone response compensation techniques is to determine the moving mass by measuring the mass of the moving coil, bobbin, and suspension springs before fabrication of a geophone, and stamp the determined moving mass value on the geophone. In this way, the actual moving mass value for each geophone may be ascertained and used for subsequent operations. This technique differs from conventional techniques which use the manufacturer's estimated or nominal value of the moving mass. Moreover, by using a more precise moving mass value, greater precision of the geophone response parameters may also be obtained, for example, using the impedance method described by Equations 9, 11, and 12.
According to an alternate embodiment of the present invention, another technique which may be used for determining the amount of moving mass of a geophone is to calculate the geophone's moving mass value using at least a portion of the geophone's response parameter values which have been determined using one or more of the above-described geophone response property test techniques. For example, according to one implementation, the moving mass value may be calculated using measured or calculated values for the geophone's damping factor, natural frequency, and open circuit sensitivity, as described in the equations below:
where:
In one implementation, the geophone's open circuit sensitivity may be determined, for example, by measurement and/or by using the dynamic calibration test technique. The geophone's damping factor and natural frequency may be determined, for example, using the impedance calibration test technique. According to different embodiments, for measurements involving the dynamic calibration test technique, response parameter values for the reference sensor or reference geophone may be obtained using a variety of different techniques, such as, for example, by (1) fabricating a reference geophone by measuring the moving mass, (e.g., by weighing the moving coil and recording the moving mass value before fabrication of the reference sensor), (2) using a reference sensor which conforms with a public measurement standard such as, for example, The National Research Laboratory of Metrology of Japan (http://www.nrlm.gojp/english/), (3) using the reciprocity calibration test technique, etc.
According to at least one implementation, the moving mass value is a constant which does not change with varying temperature or tilt of the geophone. Thus, once the moving mass is known, a geophone can be tested in-situ any time using one or more of the above-described techniques. Additionally, it will be appreciated that the technique of the present invention allows for improved accuracy of geophone calibration, which may be performed in-situ or before field employment.
Geophone Response Compensation
It will be appreciated that the technique of the present invention may be used to more precisely quantify the geophone response parameters, such as, for example, sensitivity, damping, and/or natural frequency. For example, by using a more precise, calculated moving mass value, the impedance test may be used to more precisely quantify the geophone response parameters, such as, for example, open circuit sensitivity, open circuit damping, and/or natural frequency. Consequently, the improved accuracy of the geophone response parameters not only allows the geophone to be calibrated with greater precision, but also allows for greater accuracy of geophone response compensation techniques.
According to various embodiments of the present invention, a variety of different geophone response compensation techniques may be used to achieve greater accuracy of the geophone response characteristics and/or measurements. For example, in at least one implementation, geophone response parameters values (which, for example, may be determined during geophone calibration) are used to compensate and/or transform the geophone response output signal(s) in a manner which provides greater accuracy and/or better approximates ideal geophone response characteristics. According to different embodiments, such ideal geophone response characteristics may include, for example, geophone response signals which exhibit zero phase characteristics, geophone response signals which exhibit symmetry characteristics, etc.
According to a specific embodiment of the present invention, a transfer function may be used to transform geophone response output signal(s) in a manner which better approximates ideal geophone response characteristics. In one implementation, the transfer function may be derived using information relating to the geophone response parameter values. Since the transfer function of an ideal geophone response is also known (e.g., for a geophone with the following properties: natural frequency=10 Hz, open circuit sensitivity=30 V/m/s, open circuit damping=0.4, DC resistance=375 ohm, effective moving mass=10 gram), it is then possible to transfer or transform the geophone's response signals to the ideal geophone response. An example transformation may be implemented using the following equation:
where:
According to different embodiments, the geophone response compensation technique of the present invention may be applied to individual geophones as well as an array of geophones. For example, in one implementation, the geophone response compensation technique of the present invention may be applied to an array of geophones using, for example, the moving mass value which represents the average moving mass value of the geophone array. Moreover, even in situations where it is determined that selected geophones are out of tolerance, the geophone response compensation technique of the present invention may be used to compensate the output data from the out of tolerance geophones in order to transform such data into a valid, usable data.
Geophone Response Compensation for Vibroseis
Sign=ifft{fft(Sigm)*H(fn,ζn,Sn,DRCn)} (19)
where:
In each of the embodiments illustrated in
In the example of
It will be appreciated that the technique of the present invention may be used to minimize the phase of correlated geophone the response signals. Moreover, using the geophone response compensation technique of the present invention, true zero phase may be obtained for correlated geophone response signals.
Determining Geophone Response Parameters
The following section provides a more detailed discussion of various techniques which may be used for obtaining and curved accuracy in the measurement of geophone response parameters.
As described previously, the measured values of many geophone response parameters (such as, for example, natural frequency, damping factor, sensitivity, DC resistance, etc.) are dependent upon external factors such as, for example, temperature and tilt of the geophone. By measuring the DC resistance (DCR) at working conditions, it is possible to determine the actual or real-time temperature of a geophone. Once the real-time temperature of the geophone has been determined, the values of other response parameters (e.g., damping factor, sensitivity and natural frequency) of the geophone may then be accurately calculated for the actual working temperature of the geophone.
For example, for standard copper magnetic wire, the DCR may be expressed as a function of temperature as according to:
where Cr=(0.393%)/° C.
In the impedance calibration test technique for performing geophone calibration, the DCR is typically measured by a multimeter. The calibration test technique may then be used to calculate natural frequency, open circuit damping and sensitivity. However, the present inventive entity has determined that independent DCR measurement (obtained, for example, by multimeter testing) may result in the calculation of multiple possible values for damping factor and sensitivity. Accordingly, in at least one embodiment, the DCR value may be calculated or measured using the impedance calibration test technique. The discussion below briefly describes how four geophone response parameters are calibrated by injecting signals at two different frequencies. More specifically, according to a specific embodiment, values for four unknown geophone response parameters, namely, DCR (r), natural frequency (ω0), damping factor (ζ0), and sensitivity (S0) may be determined by solving four impedance equations derived from two impedance measurements using two different frequencies ω1 and ω2.
The equation of motion for the moving coil may be expressed as:
The moving coil generates an electric signal eg proportional to the velocity of the motion relative to the magnetic field, which may be expressed as:
Equation (A1) may be rewritten in terms of eg as:
Since the geophone output signal may be expressed as:
e0=eg+ri (A4)
Equation (A3) may be rewritten in terms of the geophone output signal as:
Laplace transformation of Equation (A5) yields geophone impedance as:
Equation (A6) may be rewritten as:
Real and imaginary parts of impedance may be calculated according to:
The real and imaginary parts of the impedance equation may be represented as a circle on a complex plane, as shown, for example, in
The square sum of Equations (A8) and (A9) yields an expression:
Equation (A10) may be represented by the circle in
a2={Re(Z)−c}2+{Im(Z)}2 (A11)
The center c of the circle is given by:
Computation for geophone parameters may be expressed by:
Measurement of impedance at two frequencies, ω1 and ω2, gives four equations for real and imaginary parts of two impedances, as illustrated, for example, by Equations (A14)-(A17):
From these four equations, it is possible to derive four geophone parameters, r, ζ0, ω0, and S0.
Inserting Z1 and Z2 into Equation (A11) gives the center and radius of the impedance circle.
The DC resistance r may then be calculated according to:
r=c−a (A20)
From the four impedance Equations (A14)-(A17), ζ0, ω0, and S0 may be determined according to:
It should be noted that ζ0, and S0 may also be found as:
The values for ζ0, and S0 calculated from Equations (A13) and (A24) agree with the amounts calculated from Equations (A25) and (A26) as long as r is calculated from Equations (A18), (A19), and (A20). However, if r is measured by using a separate instrument, such as a multimeter, for example, then the values for ζ0, and S0 may not agree.
Generally, the geophone calibration and compensation techniques of the present invention may be implemented on software and/or hardware. For example, they can be implemented in an operating system kernel, in a separate user process, in a library package bound into network applications, on a specially constructed machine, or on a network interface card. In a specific embodiment of this invention, the technique of the present invention is implemented in software such as an operating system or in an application running on an operating system.
A software or software/hardware hybrid implementation of the geophone calibration and compensation techniques of this invention may be implemented on a general-purpose programmable machine selectively activated or reconfigured by a computer program stored in memory. Such programmable machine may be implemented on a general-purpose network host machine such as a personal computer or workstation. Further, the invention may be at least partially implemented on a card (e.g., an interface card) for a network device or a general-purpose computing device.
Referring now to
CPU 62 may include one or more processors 63 such as a processor from the Motorola or Intel family of microprocessors, or the MIPS family of microprocessors. In an alternative embodiment, processor 63 is specially designed hardware for controlling the operations of network device 60. In a specific embodiment, a memory 61 (such as non-volatile RAM and/or ROM) also forms part of CPU 62. However, there are many different ways in which memory could be coupled to the system. Memory block 61 may be used for a variety of purposes such as, for example, caching and/or storing data, programming instructions, etc.
The interfaces 68 are typically provided as interface cards (sometimes referred to as “line cards”). Generally, they control the sending and receiving of data packets over the network and sometimes support other peripherals used with the network device 60, such as, for example, display devices 70 and/or printing devices 72. It will be appreciated that the various geophone calibration and compensation techniques of the present invention may generate data or other information to be presented for display on electronic display devices and/or non-electronic display devices (such as, for example, printed for display on paper).
Examples of other types of interfaces that may be provided are Ethernet interfaces, frame relay interfaces, cable interfaces, DSL interfaces, token ring interfaces, and the like. In addition, various very high-speed interfaces may be provided such as fast Ethernet interfaces, Gigabit Ethernet interfaces, ATM interfaces, HSSI interfaces, POS interfaces, FDDI interfaces and the like. Generally, these interfaces may include ports appropriate for communication with the appropriate media. In some cases, they may also include an independent processor and, in some instances, volatile RAM. The independent processors may be used, for example, to handle data processing tasks, display tasks, communication tasks, media control tasks, etc.
Although the system shown in
Regardless of network device's configuration, it may employ one or more memories or memory modules (such as, for example, memory block 65) configured to store data, program instructions for the general-purpose network operations and/or other information relating to the functionality of the geophone calibration and compensation techniques described herein. The program instructions may control the operation of an operating system and/or one or more applications, for example. The memory or memories may also be configured to store data structures, seismic logging information, geophone response parameter information, vibroseis prospecting information, and/or other specific non-program information described herein.
Because such information and program instructions may be employed to implement the systems/methods described herein, the present invention relates to machine readable media that include program instructions, state information, etc. for performing various operations described herein. Examples of machine-readable media include, but are not limited to, magnetic media such as hard disks, floppy disks, and magnetic tape; optical media such as CD-ROM disks; magneto-optical media such as floptical disks; and hardware devices that are specially configured to store and perform program instructions, such as read-only memory devices (ROM) and random access memory (RAM). The invention may also be embodied in a carrier wave traveling over an appropriate medium such as airwaves, optical lines, electric lines, etc. Examples of program instructions include both machine code, such as produced by a compiler, and files containing higher level code that may be executed by the computer using an interpreter.
Although several preferred embodiments of this invention have been described in detail herein with reference to the accompanying drawings, it is to be understood that the invention is not limited to these precise embodiments, and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope of spirit of the invention as defined in the appended claims.