Trap-jaw ants In trap-jaw ants (
Odontomachus bauri) ballistic movement can be seen in their extremely rapid mandible strikes. The trap-jaw ants mandible has an average closing speed of 38.4 m/s and can produce forces that are 371-504 times the weight of the ant. The ants use these extremely powerful mandible strikes in several novel ways. When the ant attacks a larger animal it will strike the animal and at the same time use the force from the strike to propel itself away from the animal. When facing prey of similar size such as another ant the strike actually results in both animals being propelled away from each other. When the ant is trying to flee from a predator it will strike at the substrate and propel itself vertically into the air.
Crickets In crickets (
Acheta domesticus) ballistic movements can be seen in the way they jump. The kicks that propel the cricket occur over a period of only 2-6ms, but during the 18-40ms prior to the kick the potential energy required is built up by the co-contraction of the antagonistic extensor and flexor tibiae. The crickets can also use these same ballistic movements for swimming.
Cone snail In the cone snail (
Conus catus) ballistic movement can be seen in the way that it fires is harpoon-like radular tooth into its prey. After the cone snail’s proboscis comes in contact with its prey the tooth is ejected 240-295 ms later. It is believed that the propulsion of the tooth is accomplished by pressurizing the fluid space behind the tooth.
Salamanders, toads, and chameleons In
Salamanders,
Toads, and
Chameleons ballistic movement can be seen in their tongue projection which is controlled by an elastic recoil mechanism. The orientation of the muscle fibers is significant because it is what allows ballistic movements to be possible. In chameleons, the
muscle fibers used for ballistic tongue movements were found to be in a spiral orientation, with an equal amount of fibers oriented clockwise and anti-clockwise to prevent torsional movement of the tongue during projection. The internal fiber angles are approximately 45 degrees, which is the theoretical optimum to create an equal strain throughout the accelerator muscles. In salamanders of the genus
Hydromantes, the pattern of muscle activation has been mapped. The main muscles used for ballistic tongue movements in these salamanders are the subarcualis rectus (SAR) muscles. These SAR muscles can be further divided into anterior (SARA) and posterior (SARP). The first muscle to be activated is the SARA, which is located near the back of the head. The SARA remains active until the tongue makes contact with the prey. Next, the posterior SARP, located further back on the medial and lateral sides of the salamander is activated. Then the middle SARP is activated and the anterior SARP is the last to be activated. The time between activation shortens and duration of activation increases with increasing prey distance. Ballistic tongues have evolved two times previously in the Hemidactyliini and Bolitoglossini genera. The exact mechanisms of tongue projection vary slightly throughout the taxa, but the resulting projections have remained relatively constant.
Frogs do not have a specialized muscular structure for tongue projection. They are able to bypass this issue by using very rapid jaw movement to project the tongue forward. Present in all frogs are the two mandibular muscles that are used to control the jaw and, therefore, tongue projection. The m.
genioglossus is used to protract the tongue and the m.hyoglossus is the tongue retractor. Both of these muscles have longitudinally oriented fibers, which is in contrast to the spiral oriented fibers of the chameleon.
Application in humans In human, ballistic movements involve spontaneous propulsion of the limbs. This can be seen in daily routines such as reach and strike reactions, which are atomic by nature. Pointing gestures and placing an object are reach reactions; they have low acceleration and deceleration. On the other hand, punching and throwing are strike reactions; they are characterized by high acceleration and deceleration. These movements have highly variable target locations, and they are referred to as “ballistic” in
kinesiology. During ballistic movement an initial impulse is needed to accelerate the limb (hand/foot) toward the target, then a decelerating impulse act as a brake to stop the movement. These movements are characterized by a bell-shaped velocity profile. The Bayesian Model (see
Bayesian network), which was developed to perform recognition without pose-tracking, explains human ballistic movement as a sequence of movements between objects and the environment. Each movement is independent from precedent and subsequent one, in varying context. Fast single joints movement in humans is controlled by a series of activation of agonist, antagonist and then agonist muscles; this process is called triphasic activation. Those movements are executed “with a pattern of bursts in the agonist and antagonist muscles of fairly constant duration but different amplitude…” (Acornero et al. 1984). Any ballistic movement involving two joints will require an agonist and an antagonist burst; this can be viewed as the building blocks for different types of ballistic movements. ==References==