Abstract:
A system for identifying ultrasonic displacements in a material under test utilizing a time-varying output pulse of a first laser beam. The system includes a seed laser light source for providing a laser beam, a modulating assembly in the path of propagation of the laser beam for time-varying of the laser beam, at least one optical isolation assembly placed in the path of propagation of the laser beam for preventing reflected laser light feedback into the seed laser light source, and at least one laser light amplification assembly placed in the path of propagation of the laser beam for amplifying the laser beam which passes the amplified time-varying output pulse of the laser beam.

Description:
TECHNICAL FIELD OF THE INVENTION  
         [0001]    The present invention relates generally to a field of optical information processing and more particularly to a method and system for detecting ultrasonic displacements in a material under test utilizing a time-varying output pulse of a laser beam.  
         BACKGROUND OF THE INVENTION  
         [0002]    In recent years, the use of advanced composite structures has experienced tremendous growth in the aerospace, automotive, and many other commercial industries. While composite materials offer significant improvements in performance, they require strict quality control procedures in the manufacturing processes. Specifically, non-destructive evaluation (“NDE”) methods are required to assess the structural integrity of composite structures, for example, to detect inclusions, de-laminations and porosities. Conventional NDE methods, however, are very slow, labor-intensive, and costly. As a result, testing procedures adversely increase the manufacturing costs associated with composite structures.  
           [0003]    Various systems and techniques have been proposed to assess the structural integrity of composite structures. One method to generate and detect ultrasound using lasers discloses the use of a first modulated, pulsed laser beam for generating ultrasound on a work piece and a second pulsed laser beam for detecting the ultrasound. Phase modulated light from the second laser beam is then demodulated to obtain a signal representative of the ultrasonic motion at the surface of the work piece.  
           [0004]    Another method to generate and detect ultrasound using lasers discloses the use of a laser to detect deformations of a oscillatory or transient nature on a material under test surface. The deformations on the material under test surface can be produced by an ultrasound wave or other excitation. Light from the laser is scattered by the deformations, some of which light is collected by collecting optics and transmitted via a fiber optic to a beam splitter which deflects a small portion of the collected light to a reference detector and delivers the remaining portion of the light to a confocal Fabry-Perot interferometer, which generates an output signal indicative of the deformations on the material under test surface. The reference detector measures the intensity of the scattered laser light at the input of the interferometer to generate a reference signal. A stabilization detector measures the intensity of the scattered laser light at the output of the interferometer to generate a prestabilization signal. The ratio of the reference signal to the prestabilization signal is used to generate a final stabilization signal which drives a piezoelectric pusher inside the interferometer to adjust its resonant frequency.  
           [0005]    The advanced composite structures often attenuate ultrasound within the composite materials. It would be desirable to have a system capable of expanding the dynamic range of ultrasound detection in an attenuative material such as advanced composites.  
           [0006]    The above-referenced methods attempt to reduce the noise associated with the detection schemes. However, the methods disclosed do not explore expanding and improving the dynamic range of ultrasound detection in attenuative materials.  
           [0007]    Therefore, there is a need has arisen for a method and system of ultrasonic laser detection that overcomes the disadvantages and deficiencies of the prior art. Namely, such a system should be able to extend the dynamic range of ultrasound detection in an attenuative material.  
         SUMMARY OF THE INVENTION  
         [0008]    The present invention provides a method and system for detecting ultrasonic displacements at a remote target under test utilizing a laser beam that substantially eliminates or reduces disadvantages and problems associated with previously developed ultrasonic detection systems.  
           [0009]    More specifically, the present invention provides a system for detecting ultrasonic displacements at a remote target with a laser beam having a time dependent pulse profile. The system and method for improving the dynamic range of laser detected ultrasonic in attenuative materials includes a seed laser light source. This laser source produces a laser which is modulated by an assembly placed in the laser beam&#39;s path. The modulated laser has a time-dependent pulse profile. Ultrasonics at the remote target further modulate, reflect and/or scatter the laser beam to produce phase-modulated light. Optics collect this phase modulated light. An interferometer coupled to the collection optics demodulates the phase-modulated light and provide an output signal representative of the ultrasonics at the remote target.  
           [0010]    A processor may be utilized to process output signal of the interferometer to obtain data representative of the ultrasonics.  
           [0011]    Another embodiment of the present invention involves matching the time-dependent pulse profile of the detection laser beam to the attenuative properties of the remote target. Alternatively, the time-dependent pulse profile may be varied to increase the signal strength of the detected ultrasonics.  
           [0012]    The present invention provides an important technical advantage by extending the dynamic range of a Laser UT system. Previous systems would synchronize the generation of the ultrasonic event with the peak of the detection laser to maximize signal-noise-ratio without regard for potential dynamic range improvements based on exploiting non-uniform illumination profiles, while the present invention provides that the use of time-dependent detection laser illumination profiles can be used to both optimize signal-noise-ratio and extend the dynamic range of the Laser UT systems.  
           [0013]    Another technical advantage of the present invention is an extended dynamic range with which to detect ultrasound in the material under test and improved signal-to-noise ratio due to the time-varying pulse profiles of the detection laser.  
           [0014]    Yet another technical advantage of the present invention is the ability to use a detection laser with lower output power. This allows the use of smaller collection optics and optical scanners. Additionally, the use of a lower power detection laser reduces the total power applied to the material under test and damage of the material under test.  
           [0015]    Stored energy in amplifier can be extracted in an optimum way to match the properties of the material under test.  
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0016]    For a more complete understanding of the present invention and advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings in which like reference numbers indicate like features and wherein:  
         [0017]    [0017]FIG. 1 depicts a known setup for detecting ultrasonic displacements using a detection laser beam;  
         [0018]    [0018]FIG. 2 illustrates shows an embodiment of the present invention using a time-dependent output pulse profile to yield an improved signal-to-noise ratio;  
         [0019]    [0019]FIG. 3A illustrates a gaussian or lorentzian time-dependent pulse profile;  
         [0020]    [0020]FIG. 3B illustrates a linear ramp to a gain clamped time-dependent pulse profile;  
         [0021]    [0021]FIG. 3C illustrates an exponential ramp to a gain clamped time-dependent pulse profile; and  
         [0022]    [0022]FIG. 4 illustrates a typical plot of frequency dependent material attenuation.  
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0023]    Preferred embodiments of the present invention and its advantages are understood by referring to FIGS. 1 through 6 of the drawings, like numerals being used for like and corresponding parts of the various drawings.  
         [0024]    [0024]FIG. 1 illustrates a detection system  100  for detecting ultrasonic displacements  102  at remote target  104 . Detection system  100  utilizes a detection laser source  106  to generate a laser beam  108 . Detection laser source  106  may incorporate a multi-pass optical amplifier  110 , driven by pump source drive electronics  109  to generate laser beam  108  with a power P 0 . Ultrasonic displacements  102  at remote target  104  modulate, scatter and reflect detection laser beam  108 . When detection laser beam  108  interacts with the ultrasonic waves or displacements  102  present at remote target  104 , detection laser beam  108  is reflected or scattered as phase-modulated light  112 . Phase-modulated light  112  is reflected and scattered in all directions as shown by arrows  114 . However, some of the phase-modulated light  112  is captured by collection optics  116 . Collection optics  116  direct phase-modulated light  112  via fiber optic  118  into interferometer  120 . Interferometer  120  demodulates the phase-modulated light and directs an output into detector  122  which generates an analog signal for processing.  
         [0025]    Scattering of the laser beam by the material under test includes all reactions between laser beam  108  and the material under test where laser beam  108  is redirected without otherwise altering the laser beam; furthermore scattering a laser beam by the material under test includes all reactions between the phase modulated light and the material under test with the exception of absorption of the first pulsed laser beam.  
         [0026]    Collection optics  116  has an aperture size of φ and is spaced a distance D from remote target  104 . The power of the collected, phase-modulated light as measured at the output of the collector is P c . The power of the collected, phase-modulated light at the input of the interferometer is substantially P c  since there is very little transmission loss associated with fiber optic  118 . Because the loss in interferometer is minimal, the power of the input signal to the detector (P DET ) is substantially the same as P c .  
         [0027]    The signal-to-noise ratio of detector  122  is directly proportional to the square root of the input power: 
         SNR ∝ {square root}P DET   eqn (1) 
         [0028]    The above formulas suggest that the SNR can be improved by increasing P o , or φ, or by decreasing D. Increasing the ratio of  φ /D decreases the depth of field of detection system  100 , which is undesirable because a decreased depth of field is less flexible.  
         [0029]    Alternatively, P o  can be increased. One approach to increase the output of detection laser  106  is to use a shorter pulse width. The pulse of detection laser beam  108 , however, must be of a sufficient width to permit detection of ultrasonic displacements, and therefore, decreasing its pulse duration degrades its ability to detect such displacements. A second approach is to amplify the detection laser using a multiple pass optical amplifier. However, the gain of a conventional optical amplifier is dependent upon the power of the input signal.  
         [0030]    Where the P DET  is given by eqn (2):  
         P     D                 E                 T       =           P   0     4            (     φ   D     )     2            (     1   -   A     )     ·   cos                     σ   ·   η       ⇐     f                 o                 r                 a                 diffuse                 surface                             
 
         [0031]    Where P D =incident power  
         [0032]    A=absorption  
         [0033]    σ=incident angle  
         [0034]    η=efficiency (mirror losses, fiber losses, etc.)  
         [0035]    [0035]FIG. 2 illustrates a setup for generating and detecting ultrasonic displacements using a detection laser beam similar to that of FIG. 1. Detection system  200  utilizes a detection laser  130  to detect ultrasonic displacements  102  on a remote target  104 . Detection laser  130  may incorporate an electro optic phase modulator  132  to modulate the laser based on time varying drive voltage. Optical isolator  134  and beam dump  136  to prevent optical feedback into modulator  132 . Optical amplifier  138  amplifies the laser beam to produce laser beam  140  with a power P (t) . This laser beam  140  can have a time-dependent pulse profile P (t) , this pulse profile can be optimized as to improve the signal strength. This time-dependent pulse profile can be optimized to substantially match the attenuation characteristics of remote target  104 . Alternatively, a time-dependent pulse profile can be used which does not match attenuation characteristics of remote target  104  but does provide sufficient variation in the intensity of the pulse profile to alter the dynamic range of the ultrasonic detection process. FIGS. 3A through 3C illustrate potential pulse shapes, including a gaussian or lorentzian pulse shape as shown in FIG. 3A; a linear ramp/gain clamping pulse shape as shown in FIG. 3B; and an exponential pulse shape as shown in FIG. 3C. The present invention need not be limited to the time-dependent pulse profiles described in FIGS. 3A through 3C. Rather, advantageous pulse profiles may be taken such that the signal strength actually increases during the duration of the detection pulse.  
         [0036]    The present invention provides a system for detecting ultrasonic displacements at a remote target. The ultrasonic displacements  102  at remote target  104  modulate, scatter and reflect detection laser beam  140 , represented by arrows  142  directed away from the remote target  104 . When detection laser beam  140  interacts with ultrasonic waves  102 , detection laser beam  140  is reflected and/or scattered as phase-modulated light  142 . This phase-modulated light contains information representative of the ultrasonic displacements  112  at remote target  104 .  
         [0037]    Ultrasonic material displacements  102  are a function of both time and attenuation of the material from which remote target  104  is constructed. This function is shown below in Equation 1. 
           U   (t)   =U   0   e   −α     (f)·t     (EQN 1) 
         [0038]    Where α (f)  is the frequency dependent material attenuation as shown in FIG. 4. The measured signal at the detector is given by Equation 2, as follows: 
           S   (t)   =K·P   (t)   ·U   (t)   (EQN 2) 
         [0039]    Where K is a constant, P (t)  is the detection laser power and U (t)  is the ultrasonic displacements defined in Equation 1. Over a small frequency range (Δf), the frequency-dependent material attenuation as shown in FIG. 4 can be approximated by a constant: 
         α (f) ≈α 0   
         [0040]    Further, the time-dependent pulse profile P (t)  can be adjusted such that the pulse profile of the laser  140  substantially matches the attenuation characteristics of the material under test, as shown by the below approximation: P (t) ≈e +α     0t   . These approximations associated with the exponential pulse profile of FIG. 3C, yield a measured signal described by Equation 3 below: 
           S   (t)   =K·U   0   ·e   +α     0t     ·e   −α     0t     =K·U   0   (EQN 3) 
         [0041]    Here, the pulse profile, P (t) , has been made to exactly match the attenuation loss, yielding a constant measured signal strength over time.  
         [0042]    Similarly, the pulse profiles provided in FIGS. 3A and 3B allow for an improved signal strength response utilizing a different P (t)  function.  
         [0043]    More specifically, the present invention provides a system for detecting ultrasonic displacements at a remote target with a laser beam having a time dependent pulse profile. The system and method for improving the dynamic range of laser detected ultrasonic in attenuative materials includes a seed laser light source. This laser source produces a laser which is modulated by an assembly placed in the laser beam&#39;s path. The modulated laser has a time-dependent pulse profile. Ultrasonics at the remote target further modulate, reflect and/or scatter the laser beam to produce phase-modulated light. Optics collect this phase modulated light. An interferometer is coupled to the collection optics to demodulate the phase-modulated light and provide an output signal representative of the ultrasonics at the remote target.  
         [0044]    A processor may be utilized to process the one output signal of the interferometer to obtain data representative of the ultrasonics.  
         [0045]    Another embodiment of the present invention involves matching the time-dependent pulse profile of the detection laser beam to the attenuative properties of the remote target. Alternatively, the time-dependent pulse profile may be varied to increase the signal strength of the detected ultrasonics.  
         [0046]    The present invention provides an important technical advantage by extending the dynamic range of a Laser UT system. Previous systems would synchronize the generation of the ultrasonic event with the peak of the detection laser to maximize signal-noise-ratio without regard for potential dynamic range improvements based on exploiting non-uniform illumination profiles, while the present invention provides that the use of time-dependent detection laser illumination profiles can be used to both optimize signal-noise-ratio and extend the dynamic range of the Laser UT systems.  
         [0047]    Another technical advantage of the present invention is an extended dynamic range of the system to detect ultrasound in the material under test and improved signal-to-noise ratio for the system due to the time-varying pulse profiles of the detection laser. The time-varying signal can be matched to the attenuative properties of the material, thus optimizing the signal-to-noise ratio of the output signal provided by the detection laser.  
         [0048]    Yet another technical advantage of the present invention is the ability to use a detection laser with lower output power allowing the use of smaller collection optics and optical scanners. Additionally, the use of a lower power detection laser reduces the total power applied to the material under test and damage of the material under test. This reduced power requirement is due to the improved signal-to-noise ratio and dynamic range achieved by the application of the time-varying laser pulse.  
         [0049]    Although the present invention has been particularly shown and described in detail, it should be understood that various changes, substitutions and alterations can be made hereto without departing from the spirit and scope of the invention as defined in the appended claims.