(1) This posting discusses only two modes of sane locomotion: serpentine and sidewinding (more is understood about the former; at the budding stage for the latter). No discussion about other modes of locomotion, snake swimming, or climbing a tree, because nothing is known.
(2) Locomotion. (under "Snake") Encyclopaedia Britannica, undated
https://www.britannica.com/animal/snake/Locomotion
("paragraph 1" The snake has overcome the handicap of absence of limbs by developing several different methods of locomotion, some of which are seen in other limbless animals, others being unique. The first method, called serpentine locomotion, is shared with almost all legless animals, such as some lizards, the caecilians, earthworms, and others. This is the way most snakes move and has been seen by any zoo visitor. The body assumes a series of S-shaped horizontal loops, and each loop pushes against any resistance it can find in the environment, such as rocks, branches, twigs, dust, sand, or pebbles. The environment almost always provides sufficient resistance to make movement possible, and many snake species never use any other method of locomotion. Such species, when placed on a surface providing no resistance, such as smooth glass, are unable to move, whipping and thrashing around without progress. Snakes, like fishes and eels, swim by lateral undulation, which is essentially identical to serpentine locomotion. The sea snakes, however, possess a distinct anatomy in the form of a flattened, oarlike tail")
(3) serpentine locomotion
(a) The Secret of a Snake's Slither. uploaded by National Science Foundation on June 9, 2009
https://www.youtube.com/watch?v=5CchyctRFrQ
Note: This is a recap, with anime, of the next.
(b) Hu DL et al, The Mechanics of Slithering Locomotion. PNAS, 106: 10081 (2006).
https://www.pnas.org/content/106/25/10081
(paragraph 1 of Discussion: "Our simple theoretical model based on snake friction coefficients captures the general trends found in our experiments, although predicted speeds tend be somewhat lower than those measured. We offer several possible sources of discrepancy between observed and predicted speeds. We believe that the largest contributor to these disparities is given by the dynamic load-balancing we have observed in snake locomotion. Previous investigators have observed that at high speeds, snakes lift the curved parts of their bodies off of the ground as they travel in lateral undulation and in sidewinding. This can be seen clearly in Fig 3A, which shows a corn snake slithering on a mirrored surface. Through the lens of our model, we interpret this behavior as the snake dynamically distributing its weight so that its belly is periodically loaded (pressed) and unloaded (lifted), concentrating its weight on specific points of contact. We have observed that these points of contact correspond approximately to points of zero body curvature. By incorporating into the frictional force of our model a nonuniform weight distribution that concentrates weight on points of zero body curvature [ie, load; while others segments of the snake, in curves, are lifted], we provide a mechanical rationale for body-lifting. * * * These calculations show that unloading of the model snakes' body leads to augmentation of forward speed Ūavg from 0.17 to 0.23, an increase of 35% that is in greater accordance the observed speeds")
Note:
(i) Comprehend authors' terminology:
"loaded (pressed)" -- meaning contacting the ground.
"unloaded (lifted)"
"We have observed that these points of contact correspond approximately to points of zero body curvature. * * * inflection points in shape (marked by black dots) where the load is greatest"
(ii) inflection (n): "mathematics a change of curvature from convex to concave at a particular point on a curve <the point of inflection of the bell-shaped curve>"
https://www.lexico.com/definition/inflection
(iii) Now look at Fig 3C, whose caption reads in part: "Red lines indicate sections of the body with a normal force <1; the red dot indicates the center of mass. Inflection points of body shape, shown in black, show where the load is greatest."
Take notice that the two black dots of a simulated snake usually are similarly situated in the snake body, though at one point, there is only one black dot. I view the anime (1:33 to 2:06 in the YouTube video clip) frame by frame, and stick to my conclusion.
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