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Pirates Thwarted by Sonic Weapon

Posted by CmdrTaco on from the i-assume-it-was-playing-nelly dept.

Kristian Hermansen was one of dozens to submit a story about would be pirates attempting to take control of a cruise ship of the coast of Africa, only to be twarted by some sort of sonic weapon known as an LRAD, or Long Range Acoustic Device.

7 of 599 comments (clear)

  1. Weekly piracy report by __aagctu1952 · · Score: 5, Informative

    Oh yes. Pirates are as active as ever. Only nowadays they have machine guns and RPGs instead of blunderbusses and cannons...
    Just read IMB's Weekly Piracy Report for an idea of how active and how dangerous modern pirates are.

    1. Re:Weekly piracy report by joib · · Score: 4, Informative

      I'm wondering why these cargo ships are not defending themselves. Cargo ships are pretty stable even in choppy seas, and have lots of steel to cover behind. Just a simple high power rifle with a scope, and you could pick off these pirates when they're coming in their dinky open boats way before they get into range to shoot anywhere near accurately. Hell, given a machine gun, everybody on that little pirate boat would be dead meat within seconds.

  2. Re:LRAD Countermeasure? by Reverberant · · Score: 5, Informative
    I wonder if something as simple as noise-cancellation headphones would provide significant protection against LRAD usage.

    Noise cancelling headsets (and noise cancelling technologies in general) don't work all that well for high-frequency sounds since the impinging noise and the 180-degree shifted sounds need to be perfectly aligned at the ear to cancel each other out. That's difficult to do with high-frequency sounds because of the relatively small wavelengths involved.

    Now passive hearing protectors (e.g. ear plugs) work very well at high frequencies. However, the best ear plugs reduce sound by 20-30 dB at high-frequencies. If the LRAD literature is true, and it can produce sound levels of 150 dB, than ear plugs can reduce it to 120 dB, which is still uncomfortably loud.

  3. Re:Too bad it doesn't use the brown note by slavemowgli · · Score: 4, Informative

    That's just an urban legend.

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  4. Lifting content from wikipedia? by rsborg · · Score: 5, Informative
    Since you're just cutting and pasting portions of your content from wikipedia, why don't you just paste the link?

    Something you left out from the wiki content:
    "At maximum volume, it can emit a warning tone that is 151 decibels (1000 W/m) at 1 metre, a level that is very capable of permanently damaging hearing."

    I'm not sure I'd call that "an ideal use of this technology in private sector" as you put it... ethical concerns don't just go away if you're "private sector".

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  5. Re:Too bad it doesn't use the brown note by drinkypoo · · Score: 4, Informative

    Other researchers have noted flaws in the methodology of the experiment. Rather than test the entire spectrum below 20 Hz, the MythBusters tested only three specific frequencies: 5, 7, and 9 Hz. In addition, the strategy of surrounding the subject with speakers without accounting for phase effects would have resulted in a loss of effective power being transmitted, especially at the geometrical centre of the speakers.

    Your very own link suggests that the experiment may have been flawed.

    The rumor that I've heard most often is that it's a specific frequency next to 8Hz, and that it's sort of a universal resonance frequency. (ObDisclaimer: I believe in the fractal nature of the universe.) See also: Schumann Resonance.

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  6. Re:LRAD by Technician · · Score: 5, Informative

    Can you elaborate?

    Yes.

    Sending a 1Khz tone a long distance would require a large reflector to produce a relatively tight beam. Sending a 30 KHZ tone requires a much smaller reflector to deliver the acoustic power the same distance. The small dish sends high power signals. For example if we sent 30Khz and 31Khz, they would both travel in a well defined beam as a ~30Khz signal. Unfortunately we can't hear 30 Khz ultrasonic signals (except for a few audiophiles ;-). ) Air at high volume is not linear. For example you can compress air to several atmospheres. The reverse is not true. You can not draw several atmospheres of vacuum. You are limited by the hard limit of pure vacuum. Air compressing and expanding is non-linear.

    Now enter a couple very high intensity sound waves of two frequencies. Now you have non-linear mixing. In non linear mixing (just like in a radio reciever) you get out the 2 original frequencies + the sum and the difference. Therefore 30Khz + 31 Khz is 30Khz, 31Khz, 61Khz and 1Khz. Now you have delivered a very loud and painful 1Khz sound using the tight beam delivery of 30Khz with a small dish.

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