Ad Widget

Collapse

Announcement

Collapse
No announcement yet.

accelerometer as a pickup

Collapse
X
 
  • Filter
  • Time
  • Show
Clear All
new posts

  • accelerometer as a pickup

    Here is a new idea for a pickup, it is quite linear and a different approach.
    


    Sonic Nirvana: MEMS Accelerometers as Acoustic Pickups in Musical Instruments

    By: Rob O'Reilly, Alex Khenkin, Kieran Harney, Analog Devices Inc.
    Sensors




    MEMS technology builds on the core fabrication infrastructure developed for silicon integrated circuits. Pressure sensors, one of the first high-volume MEMS applications, now monitor pressure in hundreds of millions of engine manifolds and tires; and MEMS accelerometers have been used for more than 15 years for airbag deployment, rollover detection, and automotive alarm systems.
    MEMS accelerometers are used for motion sensing in consumer applications, such as video games and cell phones while MEMS micromirror optical actuators are used in overhead projectors, HDTVs, and digital theater presentations. In recent years, MEMS microphones have begun to proliferate the broad consumer market, including cell phones, Bluetooth headsets, personal computers, and digital cameras.
    This article describes some of the key technologies deployed in MEMS accelerometer products and discusses how this technology can bring a new dimension to acoustic transducers.
    MEMS Accelerometer Technology
    The core element of a typical MEMS accelerometer is a moving beam structure composed of two sets of fingers: one set is fixed to a solid ground plane on a substrate; the other set is attached to a known mass mounted on springs that can move in response to an applied acceleration. This applied acceleration (Figure 1) changes the capacitance between the fixed and moving beam fingers.

    Figure 1. The structure of a MEMS accelerometer

    MEMS structures (Figure 2) are typically formed from single-crystal silicon, or from polysilicon deposited at very high temperatures on the surface of a single-crystal silicon wafer. Structures with very different mechanical characteristics can be created; spring stiffness, the mass of the sense element, and the damping of the structure can all be controlled and varied by design resulting in sensors that can measure fractions of one g or hundreds of g's with bandwidths as high as 20 kHz.

    Figure 2. Micrograph of the ADXL50 MEMS accelerometer's structure

    The MEMS sensing element can be connected to the conditioning electronics on the same chip (Figure 3) or on a separate chip (Figure 4). For a single-chip solution, the capacitance of the sense element can be as low as 1–2 fF/g, equating to measurement resolution in the attofarad (aF) range. In a two-chip structure, the capacitance of the MEMS element must be high enough to overcome the parasitic capacitance effects of the bond wires between the MEMS and the conditioning ASIC.



    Figure 4. Cross-section of a typical two-chip accelerometer

    Accelerometers as Vibration Measurement Sensors
    The concept of using vibration sensing transducers as acoustic pickups in musical instruments is not new. Piezo- and electromagnetic transducers are the basis for many of today's acoustic pickup applications. Tiny MEMS accelerometers are so small and low in mass that they have no mechanical or mass loading effect on the instrument, making them attractive for these applications; but to date their use has been limited due to the narrow bandwidth of commercially available acceleration sensors.
    Some recent breakthroughs in accelerometer technology have enabled the production of very small accelerometers with very wide bandwidth. A high-g (±70 g to ±500 g), single-axis accelerometer, such as Analog Devices' ADXL001 (Figure 5), has 22 kHz bandwidth and comes in a 5 × 5 × 2 mm package. This is ideal for monitoring vibration to determine the state of health of motors and other industrial equipment by detecting changes in their acoustic characteristics. This particular sensor is not sensitive enough for use as an acoustical vibration sensor for musical instruments. Also, it only senses along one axis of motion, while an ideal acoustic sensor will measure the response along all three axes. It does demonstrate, however, that full audio bandwidth acceleration transducers can be produced using MEMS technology.

    Figure 5. The frequency response curve of the ADXL001

    Low-g accelerometers can measure acceleration down to milli g's, but are typically bandwidth-limited around 5 kHz. This limitation may be associated with the fact that few commercial applications require significant bandwidth (the primary applications involve the detection of human motion or gravity-driven acceleration), so there has been little motivation to develop sensors suited specifically for audio-band measurement.
    A 3-axis accelerometer has three separate outputs that measure acceleration along the Cartesian X, Y, and Z axes. As an example, Analog Devices' ADXL330 3-axis, low-g accelerometer has a bandwidth up to 6 kHz on the X and Y axes, and around 1 kHz on the Z axis. While not ideal, this expanded bandwidth allows the part to gather useful information in the audio band. The output is analog, so it can be easily instrumented and used with standard audio recording equipment. Because its size is less than 4 × 4 × 1.45 mm (Figure 6), the sensor can fit into very small places and it does not cause mass loading or other changes in the response of the system being measured. Later we will explore how this low-g accelerometer can be applied as an acoustic pickup for a guitar.

    Figure 6. The ADXL330 MEMS accelerometer measures 4 mm × 4 mm × 1.45 mm

    Acoustic Feedback
    Beginning with the introduction of omnidirectional condenser and dynamic microphones in the mid-1920s by Søren Larsen, the Danish scientist who first discovered the principles of audio feedback (known as the Larsen effect), acoustic feedback has been a demon few audio engineers are able to totally control, making it unavoidable in live sound. The Beatles experimented with this audio artifact, then decided to add it to their memorable introduction to "I Feel Fine" in 1964. Rock 'n Roll then set out to tame the beast by embracing it, making acoustic feedback a striking characteristic of rock music. Electric guitar players such as Pete Townshend and Jimi Hendrix deliberately induced feedback by holding their guitars close to the amplifier. As the fad waned, audio engineers continued their struggle with acoustic feedback's undesirable ear-shattering effects, particularly in live sound applications. In the perfect world of a well-appointed and acoustically treated recording studio, a high-end omnidirectional microphone will record instruments with an astonishing degree of realism and fidelity. Artists who know and cherish this sound have long sought the ability to reproduce it on stage. Although recording a live show with studio sound quality is every musician's dream, it has been virtually impossible. Even if sound reinforcement rigs sounded good, arenas had excellent acoustics, and sound engineers knew everything there was to know about mixing sound and had the best gear available, there would still remain one obstacle on the road to sonic nirvana: acoustic feedback.
    Acoustic Pickups
    Acoustic feedback is typically minimized by using directional microphones. This works to a certain extent, but requires constant management by sound engineers to adapt to the changing characteristics of a stage venue.
    Musical instruments can be amplified using pickups. The technologies vary, but the basic idea is to sense the vibrations of the instrument's body directly, rather than the sound it produces in the air. The pickups generate almost no acoustic feedback, as they are not sensitive to airborne sound. However, finding a good-sounding location on an instrument body is notoriously difficult, the sonic characteristics of piezo pickups are far from perfect, and their high output impedance requires special instrument inputs or direct boxes. In addition, they can be large and can interfere with the natural acoustic behavior of the instrument.
    This leads to the idea of a low-mass contact microphone. Suppose that we use a surface transducer that measures the acceleration of the instrument's body, preferably on more than one axis. This transducer would have good linearity and be so lightweight that it would not acoustically affect the instrument being measured. Suppose further that the transducer has similar output level, output impedance, and power requirements to a traditional microphone. In short, suppose that a musician could just plug this transducer into a microphone preamp or mixer input, just like any other microphone.
    Contact Microphones
    An attentive reader will notice the mention of acceleration in the preceding paragraph. Our ears respond to sound pressure, so microphones are designed to sense sound pressure. To simplify matters greatly, the sound pressure in the immediate vicinity of a vibrating body is proportional to acceleration. What if an accelerometer had enough bandwidth to be used as a contact microphone?
    To explore this concept, we mounted a 3-axis accelerometer on an acoustic guitar to act as a pickup. The vibration of the instrument was measured and compared to the built-in piezo pickup and to a MEMS microphone mounted near the guitar. The guitar used was a Fender Stratacoustic acoustic with a built-in Fender pickup. An analog output MEMS accelerometer was mounted on a lightweight flex circuit and attached to the guitar body using beeswax at the bridge location, as shown in Figure 7. The X-axis of the accelerometer was oriented along the axis of the strings, the Y-axis was perpendicular to the strings, and the Z-axis was normal to the surface of the guitar. A MEMS microphone with a flat frequency response out to 15 kHz was mounted 3 in. from the strings for use as a reference.

    Figure 7. Accelerometer mounted on a Fender Stratacoustic Acoustic Guitar

    A short sound segment was recorded using the accelerometer, the built-in piezo pickup, and the MEMS microphone. The time domain waveforms for each transducer are shown in Figure 8. No postprocessing was done on any of the audio clips.

    Figure 8. Time domain waveforms using different transducers

    Figure 9 shows an FFT-based spectrum of the piezo pickup measured at one of the peaks in the time domain waveform. This spectrum shows a response with a strong bass component. Indeed, the actual audio file sounded excessively full, with a lot of bass response. This sounds pleasing (depending on your taste) as the cavity resonance creates a fuller bass sound than that heard when listening to the instrument directly.

    Figure 9. FFT spectrum of piezo pickup

    The MEMS microphone output is very flat and reproduces the sound of the instrument very well. It sounds very natural, well balanced, and true to life. The FFT-based spectrum measured at the same point in time as the piezo pickup is shown in Figure 10A. The frequency response of the MEMS microphone is shown in Figure 10B for reference.
    ','858','346','/sensors' ,'605587' );return false;" href="#"','858','346','/sensors' ,'605587' );return false;" href="#" Figure 10. The FFT-based spectrum of a MEMS microphone (A) and its frequency response (B) (Click image for larger version)

    The output from the MEMS accelerometer is very interesting. The immediate weak points are that the noise floor was too high and audible at the beginning and end of the track, and that the bandwidth of the Z axis was clearly limited to lower frequencies. The sound reproduction from each axis was noticeably different.
    The X and Y axes sounded bright and articulate and had clearly discernable differences in tonality. As expected the Z axis obviously sounded bass dominated. Figure 11 shows the X-axis spectrum (A), the Y-axis spectrum (B), and the Z-axis spectrum (C).


    The X, Y, and Z axes mixed together produced a fair representation of the instrument with some brightness. By adjusting the mix, a variation in tonal balance can be achieved with natural sound reproduction. The extended upper harmonics are still missing due to the bandwidth limitation of the current accelerometers, but the sound reproduction was still surprisingly true.
    Conclusion
    Low-g MEMS accelerometers do not suffer from traditional feedback problems, and demonstrate clear potential as high-quality acoustic pickups for musical instruments. A 3-axis accelerometer mounted on a Fender Stratacoustic acoustic guitar achieved promising sound reproduction. The three axes have different tonal characteristics related to the vibration modes of the instrument in the different directions of the body, however the three output channels can be mixed to generate realistic sound reproduction. In addition, these channels can be mixed in different ways to produce creative tonal effects.
    While the performance of the accelerometer in this experiment is very promising, there are a few drawbacks. The noise floor of the sensor is audible, a problem that can be minimized using noise gating or other techniques, but the ideal sensor will have a noise floor comparable to conventional microphones. The high-frequency response of the sensor needs to be extended, ideally up to 20 kHz to capture the full tonal range of the instrument.
    MEMS accelerometer technology has clear potential for acoustic pickup applications in musical instruments, especially in live performances where acoustic feedback could be a problem. A very small, low-power MEMS device can be mounted unobtrusively anywhere on the instrument without affecting its natural vibration characteristics. In fact, multiple sensors can be mounted at different points around the instrument to provide the sound engineer with additional flexibility to reproduce the natural character of the instrument without fear of acoustic feedback in live sound applications—one step closer to "Sonic Nirvana."


  • #2
    Sonic Nirvana: MEMS Accelerometers as Acoustic Pickups in Musical Instruments - Sensors
    this got chopped off, link to full text with images

    Comment


    • #3
      Optical pickup for stringed instruments -simplicity makes it.

      I attended the 1969 Chicago NAMM show. There, I showed and demonstrated my first musical instruments with the Hoag Optical Pickup. It was clear to me, they didn't understand the method or my explanation, How, a little tiny string could cause such a large output signal. Most knew of the photo tube and how a large change in light could cause a sound. Such is the method of Motion Pictures since, 1922.

      They were not alone, the U.S. Patent examiner had the same concern. That is why he ultimately denied my claims. Fortunate for me, the Canada and Mexico patent offices didn't see my claims in the same " light."

      It was and still is, my contention that the understanding of the vibrating musical instrument string is not fully grasped.
      First, the string diameter or length of the string, is of little consequence of signal output, within the optical pickup. It is the swing of such strings and the shadow of these strings, that cause the musical output. This shadow is moving across a PN junction of a Reversed-Biased Photo Diode. The intensity of the matched light source to the diode and the excursion of the stings, are the determining factors for volume output.

      The musical voltage output is enhanced by using a high impedance inductor introduced into the circuit. This also serves, as a stabilizing d.c. voltage shift, because of the low internal dc resistance. This dc shift will occur, when a higher intensity light is made to impinge upon the sting. This causes a shadow to be cast upon the PN junction, of the optical diode. The greater the movement of this shadow, without leaving the junction area, the greater the output. This output can reach to the limit of the PN junction voltage breakdown.

      Another factor of the high impedance inductor, it has the mimic capabilities to other pickups such "magnetic pickups". The inductor adds to the harmonic structure, by altering the relationship of these harmonics to each other.

      The musical notes within the vibrating strings are filled with nearly unlimited harmonics. The inductor acts as an resonant circuit to some frequencies and produces the effect of the inductance coil of the magnetic pickup. This reactance with other frequencies give us the accepted sound of the "Electric Guitar"

      The sound of the "Acoustic Guitar". Now, that is a notion. An electrical acoustic instrument.

      One other thing the optical pickup does, It sees exactly how the strings vibrate. First the fundamental and then the harmonics follow. These harmonics are a reflection of the fundamental, causing a beat against reflections of itself. The fundamental is the lowest sound of the string. But, is it?

      The sting's slightest movement is detected by the shadow and it shows a "half cycle motion" then returns to crossover point then the other "half cycle motion" is detected.

      How, curious!

      Second, the harmonics..... they shouldn't be there, at the bridge. Standing waves should be exactly where the formulas tell us.

      How, curious!

      Comment


      • #4
        Ron! Welcome to the forum! I have read all about your pickups and judging form the clips I have heard ,they sound great!

        Comment


        • #5
          Hi Ron,
          I've always wondered why a commercial pickup has not been developed, the little u shaped infrared led phototransistor units would make this easy tomount at the neck or bridge recessing the phototransistor should make it fairly immune to ambient light.
          I woukdn' worry too much about not getting a patent. I would think there is considerable prior art in reguard to modulating and detecting a beam of light, patents can be expensive to defend and the money is often better spent on engineering and marketing.

          Amplexus

          Comment


          • #6
            optical pickup sad story

            Thank you for your comments.
            When I started this invention in 1968, it was indeed state of the art. I had no idea that I would step on so many toes. Many engineers at the time was just comming to grips with the new fangled transistors. Relay logic was the rage and I remember introducing them to the latest developments in solid state logic and analog devices. I was an Electronic parts salesman for Hamilton Avnet electronics for Oregon.

            In 1970 I showed the optical pickup to Chet Atkins and he put me in touch with Gretsch Guitars. From there I showed the to Gibson Guitars and Rickenbacker Guitars. All of which wanted to take the project further, but as it turned out the music Industry wasn't ready for this technology.

            I have tried several times to bring out the optical pickup guitars on my own but as always, ran out of money.

            I still am trying to get some attention for this project. I have a you tube site.

            YouTube - ronrhoag's Channel This has videos and some information on the pickup.

            Comment


            • #7
              Over the years I have seen many optical pickup patents, but I don't think any of them became commercially successful products.

              Comment


              • #8
                Wow, Ron Hoag! Hey nice to have you here. I remember being fascinated by your pickup back in the 70's when I saw it in Guitar Player.

                Joe, there is LightWave Systems who have been making an optical pickup system for bass since the late 90's. I don't know how many basses they sell, but they are still around.
                It would be possible to describe everything scientifically, but it would make no sense; it would be without meaning, as if you described a Beethoven symphony as a variation of wave pressure. — Albert Einstein


                http://coneyislandguitars.com
                www.soundcloud.com/davidravenmoon

                Comment


                • #9
                  Originally posted by Amplexus View Post
                  Hi Ron,
                  I've always wondered why a commercial pickup has not been developed, the little u shaped infrared led phototransistor units would make this easy tomount at the neck or bridge recessing the phototransistor should make it fairly immune to ambient light.
                  I woukdn' worry too much about not getting a patent. I would think there is considerable prior art in reguard to modulating and detecting a beam of light, patents can be expensive to defend and the money is often better spent on engineering and marketing.

                  Amplexus
                  The good news is that now the prior art can't be used against you for the "machine" but sadly you have dedicated the "method" to the public.

                  Ron, did you claim the machine or the method?

                  The method should have been unique:

                  "I claim:

                  1. A method for translating mechanical musical energy from stringed musical instruments into electrical impulses for the purpose of audible amplification."

                  (I would add this one too)

                  2. A method for translating mechanical musical energy from stringed musical instruments into electrical impulses for the purpose of digital conversion." (MIDI)

                  The method is the implementation of your invention. I'm only guessing, but "obviousness" should not have come into play in denying your application under this type of claim because one element, stringed instrument amplification, was not in existence at the time of your invention.

                  Comment


                  • #10
                    L.R. Baggs does a mandolin pickup with an accelerometer. It sounds absolutely fantastic!

                    Comment


                    • #11
                      Optical pickups

                      Thank you for your comments.
                      Yes, Light wave has an optical pickup bass. One of their investors called me in the 1990's to make a deal with me. I said, no. in retrospect, I may have been better off if I did. Who, knew?

                      Dave, I took a look at your web site and you guitars are gorgeous. I haven't down loaded tunes yet but I will.

                      Comment


                      • #12
                        Hey Ron -welcome, another Oregonian to the mix...
                        I've played around with the LightWave pickups a few years ago and they don't use photo transistors. I'm pretty sure it's just a pair of solar cells side by side with an infrared led casting the string shadow so that as the bass string moves one way the voltage drops as the string's shadow covers more of one cell or the other. One cell generates the + and the other is generating the - so you end up with a very low voltage sin-wave as the shadow swings back an forth.

                        It only works with thicker bass strings and the sensor needs to be very close to the saddle or the excursion gets too big and the tops of the waves get flattened.

                        What's nice is that you can make an almost passive pickup in this way (except for the light source).

                        Comment


                        • #13
                          Has anyone played around with the micro-accelerometers? They seem very linear and sampling the vibration in 3 different axis opens up some interesting mixing possibilities. AD has always been good about providing free samples.
                          Amplexus

                          Comment


                          • #14
                            optical pickup

                            I had to be careful when describing the sting and photo cell. The patent examiner kept giving references to a vibrating reed in front of a photo tube and said that was "prior art". It was an invention for electric organs. Meisner, I belive

                            Comment


                            • #15
                              Are there sound samples for the mandolin accelerometer pickup on line? these things are fairly cheap and very linear at guitar frequencies there should be no hum.

                              Comment

                              Working...
                              X