8 October 2015 Laboratory tools and e-learning elements in training of acousto-optics
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Proceedings Volume 9793, Education and Training in Optics and Photonics: ETOP 2015; 97930U (2015) https://doi.org/10.1117/12.2223088
Event: Education and Training in Optics and Photonics: ETOP 2015, 2015, Bordeaux, France
Due to the acousto-optic (AO) effect, the refractive index of an optical interaction medium is perturbed by an acoustic wave induced in the medium that builds up a phase grating that will diffract the incident light beam if the condition of constructive interference is satisfied. All parameters, such as magnitude, period or phase of the grating can be controlled that allows the construction of useful devices (modulators, switches, one or multi-dimensional deflectors, spectrum analyzers, tunable filters, frequency shifters, etc.) The research and training of acousto-optics have a long-term tradition at our department. In this presentation, we introduce the related laboratory exercises fitted into an e-learning frame. The BSc level exercise utilizes a laser source and an AO cell to demonstrate the effect and principal AO functions explaining signal processing terms such as amplitude or frequency modulation, modulation depth and Fourier transformation ending up in building a free space sound transmitting and demodulation system. The setup for MSc level utilizes an AO filter with mono- and polychromatic light sources to learn about spectral analysis and synthesis. Smart phones can be used to generate signal inputs or outputs for both setups as well as to help students’ preparation and reporting.
Barócsi, Lenk, Ujhelyi, Majoros, and Maák: Laboratory tools and e-learning elements in training of acousto-optics



Acousto-optics in the scientific literature will definitely refer to the more than 50 years of technological progress initiated by the development of the laser in 1960. It became obvious that utilizing the acousto-optic (AO) effect provides an elegant way for influencing photons by altering the refractive index of the medium in which the light propagates.

The story begun in 1922 when L. Brillouin was investigating the properties of acoustic waves induced thermally in liquids and solids1. According to his model, the acoustic fluctuations yielded a periodic change of the density of the propagation medium resulting in an alteration of the dielectric permittivity. If so, this change could be determined from the scattering pattern of a light wave with appropriately short wavelength. Brilluein himself proposed the analogy between this scattering phenomenon and the diffraction of light from periodic structures (studied by W. H. Bragg and W. L. Bragg in the 1910s). Thus, the incidence angle of the light beam must be chosen so as to obtain constructive interference. A principal difference, he argued, was that an acoustic wave created a sinusoidal grating that allowed only two (±1) diffraction orders and the corresponding critical angles. Later, this phenomenon was termed Bragg diffraction. There is another distinction from an optical grating: the acoustic grating propagates with the speed of sound, hence the frequency of light is Doppler shifted by the acoustic frequency with opposite signs for the two orders.

There was 10 more years passed till the experiments were realized by P. Debye and F. W. Sears, as well as R. Lucas and P. Biquard demonstrating the AO effect by ultrasonic waves in liquids and solids2, 3. The results were, however, surprisingly different from Brilluein’s predictions: the critical angles could not be demonstrated and, for intense acoustic field, more than two orders appeared due to the small interaction volume as Debye and Sears realized. The finding is worth emphasizing that constructive interference can be maintained in a wide angular range: this fact allows for a finite interaction bandwidth being one of the most important parameters in terms of practical application of AO devices.

Although the AO effect was nicely formulated analytically later verified by a few experiments, not until the ‘laser era’ its practical application advanced. Then a boom in applied acousto-optics initiated from the various light controlling AO devices, such as traveling and standing wave modulators4 and switches5, single or multi-dimensional deflectors6, tunable filters7 and frequency shifters8 to the sophisticated AO signal processing systems such as a real time power spectrum analyzer9, direction of arrival processor10, or 3-dimensional (3D) AO light steering in multi-photon microscopy11. This progress seemed to cease by the spreading of laser diodes allowing a direct fast modulation of light. However, it has again been boosted by the utilization of the AO effect in the dispersion control and shaping of ultrafast laser beams12.

The research and development of AO devices, systems and technology as well as the accompanying training of acoustooptics at different levels of the education have a long-term tradition at the Department of Atomic Physics dating back to the 1980s. Although training starts at BSc level of higher education in physics, several demonstration activities involving acousto-optics present each year for secondary school pupils orienting them among faculties and specializations. The training continues at MSc then PhD levels offering research activities in the topic13. Next, we introduce this training set in the framework of two related laboratory exercises set at BSc and MSc levels. Recently, e-learning elements have been being developed accompanying the training to help students’ laboratory preparation, work and reporting.



Within the framework of the BSc in Physics program, basics of acousto-optics are demonstrated in the Advanced Physics Laboratory 2 simultaneously with Optics in the 4th semester, in which subject its fundamental theory is taught, as summarized below.


Basic concepts of acousto-optics

Due to the photoelastic effect, propagation of an acoustic wave in a medium induces a periodic change of its refractive index yielding a phase grating that travels at a speed of the acoustic wave in the medium. The gratings constant equals to the acoustic wavelength λa, whereas the magnitude of the grating is proportional to the acoustic amplitude S0 and the magnitude p of the photoelastic effect. According to Figure 1a, consider an acoustic plane wave with wave vector 00022_psisdg9793_97930U_page_2_8.jpg and angular frequency ωa that propagates in the 00022_psisdg9793_97930U_page_2_10.jpg direction of the xz plane

Figure 1.

Geometry of the AO interaction (a) with the refractive index change (b) and the wave vector matching for m = 1 at the Bragg condition (c). Association can also be made to the scalar diffraction model (d) that applies field decomposition into plane waves at an aperture with complex transmittance function τ (r).


and an optical plane wave with k0 and ω0 propagating in the direction characterized by the internal angle θ0 from the x axis. Propagation of the optical beam in the medium is given by the wave equation


where c is the speed of light in vacuum and n(x, t) is the refractive index of the medium (Figure 1b), approximated as


with effective index n for small δn = pn3S0/2 magnitude of the index change. As the electromagnetic field is periodic, it can be decomposed into a Fourier-series14. Putting the Fourier decomposition into the wave equation and omitting higher order components, for scalar, slowly varying field, i.e. 00022_psisdg9793_97930U_page_2_9.jpg, yields


for the Em = Em(z) amplitude of order m = {0,±1,±2,…} with wave number kυ= 2π/λυ in vacuum and the Bragg angle


ensuring constructive interference. Equation (5) can be generalized by applying the conservation of momentum for the interaction in terms of the wave vector matching (Figure 1c),


whereas the energy is conserved through the frequency condition of


Although the derivation of the so called coupled wave equation (4) being fundamental in the quantitative description of the AO effect goes beyond this training level, its visual interpretation in the course of the laboratory exercise is well fit into the scalar diffraction theory using Fourier decomposition as taught in the course of subject Optics (Figure 1d). This aspect also explains the term Bragg diffraction occurring from thick volume grating as opposed to a thin grating producing many diffraction orders. In general, higher orders may exist if the term in Equation (5) is small as demonstrated experimentally in Figure 2c. We recall also on the basis of the scalar diffraction theory that the full width divergence δθa and angular spectrum S(θa) of a rectangular sound column with length L is approximated as


From Equation (5) and Figure 1c, we know that the diffracted orders are separated by 2sin θB = λ0/λa, so the condition


ensures the appearance of higher orders, as depicted in Figures 2a–b.

Figure 2.

The effect of the acoustic divergence (a) on the appearance of higher diffraction orders (b). Demonstration of many AO diffraction orders (c).


On the other hand, the theory of the AO effect is introduced in Optics in a far simpler way by integrating the elementary dr complex amplitude reflectance coefficients upon planar layers separated by dx distance along the x direction (Figure 1a) to get the total amplitude reflectance15


The first derivative dr / dn of the local change of amplitude reflectance dr / dx can be obtained from the Fresnel equations whereas the second term is calculated from Equation (3). This approach explains the term Bragg reflection.


Training setup

Figure 3a shows the basic AO experimental setup. The optical elements are built upon a pre-aligned linear optical stage of to minimize the necessary adjustments. As seen from Figure 3b, the AO cell is mounted on a rotator that allows adjusting of the Bragg angle in a vertical plane. This translates to one vertical degree of freedom for adjusting the detector. A horizontal translator is also placed under the AO cell to provide fine tuning of its entrance aperture while maintaining the beam propagation in the horizontal axis of the optical stage. Key elements in the setup are a frequency generator with internal/external AM/FM modulator and a combined AO driver with switching modulator and power amplifier. The generator operates in the radio frequency (RF) range of 10 MHz to 100 MHz and its output is amplified up to a maximum of undistorted 1 W. A 633 nm He-Ne laser with 3 mW output optical power is used as a light source.

Figure 3.

Block scheme (a) and optical stage (b) of the basic AO experimental setup with many in-house made components


As a basic experiment, the AO interaction geometry can be studied according to Figure 1a together with the visualization of the diffraction orders. Given the refractive index of the AO cell made of TeO2, the sound velocity υa can be calculated from the external refraction geometry measured at the Bragg condition of Figure 1c. Also, as a practical application of the AO cell, the light deflector concept (Figure 4a) can be introduced by measuring the deflection angle Θ defined as the total external angle between the 1st and 0th order beam. Using Snells’s law


For small angles, Equation (11) simplifies to a linear Θ(fa) relationship versus acoustic frequency fa.

Figure 4.

The AO cell operated as a light deflector (a) and light modulator (b) with characteristic input and output signals. Insets of (a) show the ΔΘ scanning range and the τD transit time of the deflector. Inset of (b) shows τD for the modulator.


Figure 5.

A series of calculated uAM(t) modulated electric signal amplitude and I1(t) diffracted intensity curves at different modulation depths δAM of 0.5 (a), 1.0 (b) and 1.4 (c) with the corresponding measured oscillograms. The modulated acoustic power 00022_psisdg9793_97930U_page_5_5.jpg is also given for direct comparison to I1 (t) ~ PAM(t).


Using the photodetector and the microvolt-meter or the oscilloscope, the intensities of the diffracted orders can be determined. At the Bragg condition, the ηd diffraction efficiency is defined as the ratio of the intensity of the 1st order beam to that of the 0th order one being equal to the peak reflectance that can be obtained upon evaluating Equation (10):


At low acoustic field intensities, the efficiency is proportional to the acoustic intensity 00022_psisdg9793_97930U_page_4_4.jpg with ρ being the density of the medium or, more conveniently, to the acoustic power Pa = IaLH with L and H being the interaction length defined in Figure 1a and the width of the sound column, respectively. Idealizing that the acoustic power equals to the input electric power, PaPin, the linear ηd (Pa) relationship can be measured. To do so, the output level of the RF generator is adjustable by a rotary switch with pre-calibrated power levels.



As the RF drive power of the AO cell increases, the linear ηd(Pa) relationship will not hold. A more precise analysis (in which depletion of the incident beam is also considered) reveals the following expression:


where all material and geometric parameters are embedded in constant C. This diffraction efficiency function can also be measured versus RF driving power in the basic laboratory and will depict a curve similar to that of Figure 6a. Going to advance level, Equation (13) can be regarded as the modulation transfer function of the AO cell when considered as a light intensity modulator. To measure the temporal response of the AO cell upon an input signal, the basics of signal modulation must be introduced. Amplitude modulation (AM) of an input electric signal is the simplest mode that can be realized by means of an AO modulator (Figure 4b).

Figure 6.

Demonstration of the combined effect of over-modulation at δAM = 1.4 yielding a foldback at signal nodes and that of large acoustic power Pa at which the foldback appears at signal peaks due to the nonlinear modulation transfer function (a). Temperature dependent shift of the transfer function (from solid gray to dashed curve) is visualized in oscillograms (b) and (c): the average acoustic power 00022_psisdg9793_97930U_page_6_4.jpg inside the cell in (b) is reduced to 00022_psisdg9793_97930U_page_6_5.jpg in (c) by turning on the switching modulator with switching frequency of 10 kHz and duty cycle of 50%.


The AM modulated input electric signal can be described as


with modulation amplitude uAM (t), modulation frequency fAM and the parameter δAM defined as the modulation depth. The significance of the modulation depth can be readily demonstrated by setting up the internal AM modulation with fAM = 400 Hz. Figure 5 depicts a series of calculated electric uAM (t) to diffracted intensity I1(t) curves at different δAM values with the corresponding measured oscillograms. The modulated acoustic power, proportional to the squared modulated amplitude 00022_psisdg9793_97930U_page_5_6.jpg, is also plotted in Figure 5. From these measurements, the low distortion region at δAM < 1 and the high distortion region at δAM > 1 with the apparent foldback around the nodes can be identified. In Figure 6a, we can demonstrate the combined effect of large δAM and that of high acoustic power at which the foldback appears at the signal peaks due to the nonlinear transfer function of Equation (13). The setup can be used even to visualize the temperature dependence of the transfer function: the peak foldback in the modulated intensity of the diffracted beam (Figure 6b) will increase as the average acoustic power inside the cell is reduced (Figure 6c) due to the shift of the transfer function towards higher driving powers. The average power reduction can be accomplished by turning on the switching modulator of the combined AO driver. The modulator periodically switches on and off the input of the power amplifier at a duty cycle of 50% hence providing the same peak power at halved average power.

Finally, to complete the AO modulation basics, some useful bandwidth must be added to the modulation. Recalling Figure 1c, we know that an incident optical plane wave k0 interacting with an acoustic plane wave ka produces an optical plane wave k1 at Bragg condition. When the amplitude of an acoustic wave is AM modulated with a signal of bandwidth ΔfAM, it has frequency components within a band fAM,0 ± ΔfAM that must interact with the incident optical wave. This can be done if the divergence δθ0 λ0/D of the incident optical beam of width D is matched to the acoustic divergence δθa given in Equation (8) so that the ΔSθa) components of the angular spectrum of sound within Δθa = δθa will diffract the components of the light beam within Δθ0 = δθ0 similarly to that in Figures 2a–b:


From Equation (15), the ΔfAM bandwidth of the modulator can be expressed as


where the transit time τD of sound across the light beam is introduced. Definition of τD holds for the collimated beam of the deflector in Figure 4a and the focused beam of the modulator in Figure 4b where the beam waist diameter is taken. The transit time can easily be measured by turning on the switching modulator of the setup and measuring the rise time of the square wave modulation of the output intensity with and without the lens pairs.

Now everything has been set to assemble the AO setup as a free space sound transmitter and demodulation system according to Figure 7. The most stunning experience is playing music fed from an input source to the AO cell via the external AM input of the RF generator. The free space path is identified as the 1st order beam of the AO cell fed to the photodetector. Any device that acts as an active speaker can be used for directly demodulating the output signal of the photodetector. Now students are free to play around with any parameters of the modulator/demodulator stages.

Figure 7.

Block scheme of a free space sound transmitter and demodulation system built upon the basic AO setup.




Within the framework of the MSc in Physics, applied acousto-optics is trained in the Applied Physics Laboratory of the Applied Physics specialization. The laboratory experiment focuses on the investigation of an AO tunable filter with mono- and polychromatic light sources to learn about spectral analysis and synthesis.

A major feature of an AO filter is that its narrow spectral transmission can be electronically tuned over a wide spectral range. There are some considerations to successfully realize an AO filter of Figure 8b. Whereas the devices studied earlier typically operate at a single wavelength of a laser source, an AO filter must operate in a wide spectral tuning range Δλ = λmaxλmin utilizing a light source with broad and, ideally, uniform emission in this range. The period of the AO gratings constant, equal to the acoustic wavelength, can be tuned by the acoustic frequency to change the optical wavelength at which the Bragg condition is satisfied in a preferably narrow spectral bandwidth δλ. As such, the AO filter is an inverse deflector: at each wavelength a narrow diffraction bandwidth, hence a high resolution R = Δλ/δλ, is realized even at large input beam divergence as well as the change of the position of the diffracted beam is avoided.

Figure 8.

Anisotropic AO interaction (a) and typical geometry (b) for the AO filter with characteristic input and output signals. Note the different propagation direction of acoustic energy Sa and wavefront ka.


To satisfy all these conditions simultaneously, anisotropic AO interaction must be employed. In an anisotropic interaction, the polarization of the diffracted beam is changed. As a result, due to the birefringence of the medium, the refractive index for the diffracted beam also changes so the angles of incidence and diffraction will no longer be symmetric. Equation (6) for wave vector matching also hold for m = 1, but now the incident and diffracted wave vectors have different lengths, as illustrated in Figure 8a. A wavelength outside the Bragg condition will introduce a wave vector mismatch with magnitude Δk so the normalized transmittance Tλk) will drop as


To compensate for the larger divergence of a broadband source, the Bragg condition must not change upon the infinitesimal change of the incident angles in the interaction plane δk) / δθ0 = 0 or the orthogonal plane δk)/δφ0 = 0 imposing the condition for parallel planes16 of Figure 8a.

The breadboard of the experimental setup comprises a white LED source (Cree Xlamp XPCWHT-L1) with 150 μm pinhole and a collimator lens, an in-house made TeO2 based AO filter on kinematic mount and a photodetector unit connected to an oscilloscope. The AO filter is driven by a programmable RF generator (Rohde & Schwarz SMY01). Figure 9 plots some of the parameters that can be determined during the experiment. The wavelength dependent curves can be taken by using a fiber optic spectrometer. Alternatively, the tuning curve fa(λυ) can be extrapolated from data taken at 3 known (laser) wavelengths, then the parameters can be taken versus fa and transformed against λυ.

Figure 9.

Typical AO filter parameters determined during the experiment: (a) tuning curve fa(λυ) and spectral bandwidth δλ(λυ), (b) filter transmission curves Tλυ, Δk) and LED spectral emission TLED(λυ). Insets: AO filter (bottom), LED (top).




Recently, elements of e-Learning has been defined or introduced in the training of acousto-optics to help students’ laboratory preparation, work and reporting. A Moodle based learning management site (LMS) on a local network attached storage (NAS) server was established with a collection of course contents in downloadable PDF format or, recently, with online SCORM content. Although course materials are available from the student’s site at the department homepage, LMS offers a stricter way of management of laboratory courses.

First, preparation can be checked by scoring that students have read the required material in time prior to the laboratory. Also, a ‘pre-lab’ test can be set up outside the laboratory contact hours saving extra time for the exercise. The online content can be used throughout the exercise and it is available on mobile phones with animation, occasionally (Figure 10a). Mobile devices offer m-Learning17, so that they can form an integral part of the experiment, in addition to content viewing. As an example, in the advanced training of the basic AO setup, a mobile device can generate signal inputs for the free space transmission of Figure 7 through its headset output and record the sound of the speaker. In both setups, students are encouraged to take photos of the screen, for qualitative or even quantitative evaluation in their report. Finally, post-lab tests (Figure 10b) and online submission of reports can be initiated helping tutors in students’ evaluation such as automated checking of report submission. Whereas pre-lab tests aim at scoring students’ (theoretical) knowledge in preparation for the laboratory, post-lab tests are more practical to measure those skills gained during the experiments, as in Figure 10b that shows a fairly ‘visual’ question.

Figure 10.

Example of online content for students attending AO laboratory: AO effect animation (a) and post-lab test (b).




In this paper, an overview of training of acousto-optics has been given with a step-by-step introduction of more basic setup used at BSc and advanced levels, and with a brief description of an MSc level experiment. We conclude that both laboratories directly offer the fundamental knowledge for both undergraduate courses and advanced research in utilizing the AO effect. The training can be beneficial in a PhD thesis work13 or in a photonics related profession. For example, the concept of modulation can be readily extended to standing acoustic wave AO cells with self modulation to get mode locking of lasers with large modulation depth and low duty factor4. Deflector basics can be extended to multidimensional scanners such as those used in 3D beam steering in two-photon microscopes11. Filter configurations can be used for pulse shaping of femtosecond lasers12. Finally, e-learning elements have been introduced that help improve students’ laboratory experience and tutors’ evaluation efforts. As e-learning is quite new in this context, conclusions are awaiting.


This work has been partially funded by “TÁMOP-4.1.1.C-12/1/KONV-2012-0005 – Preparation of the concerned sectors for educational and R&D activities related to the Hungarian ELI project” supported by the European Union and co-financed by the European Social Fund.



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Attila Barócsi, Attila Barócsi, Sándor Lenk, Sándor Lenk, Ferenc Ujhelyi, Ferenc Ujhelyi, Tamás Majoros, Tamás Majoros, Paál Maák, Paál Maák, } "Laboratory tools and e-learning elements in training of acousto-optics", Proc. SPIE 9793, Education and Training in Optics and Photonics: ETOP 2015, 97930U (8 October 2015); doi: 10.1117/12.2223088; https://doi.org/10.1117/12.2223088

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