Joint-legged animals without backbones are called arthropods and are placed in the phylum Arthropoda. Human legs are jointed at the knees, but we have backbones, so we're not arthropods. On the tick at the left you can clearly see the joints.
How do you know this tick isn't an insect? The easiest thing to notice is that insects have 3 pairs of legs (6 of them) while this tick has 4 pairs (8 legs). Also, insects have 3 body regions (head, thorax and abdomen) while this tick appears to just have a head and a body. Both ticks and insects are members of the phylum Arthropoda, but ticks, along with spiders, are members of the class Arachnida, while insects belong to the class Insecta.
Here's a simplified outline showing how the best known kinds of arthropods hang together:
To see a much more complete, and confusing, breakdown, visit the NCBI taxonomy database
Keep in mind that many commonly occurring arthropods are tiny, even microscopic, such as Daphnias, sometimes called water fleas (genus Daphnia). Daphnias such as the one shown below are crustaceans often found in lakes and ponds.
The more than 200 Daphnia species range in size from 0.01 to 0.20 inches (0.2-5.0mm).
From nature's point of view, the combination of having jointed legs but lacking a backbone seems to be a good one. That's because
The word "successful" needs to be defined, for many humans would consider mammals to be earth's most successful group of animals, since humans are mammals, and humans are obviously Earth's "top dogs." However, the human standard for "success" isn't necessarily the only one. From a biological perspective, animal groups are "successful" if...
You can judge for yourself how successfully the Flame Box Crab, Calappa flammea, shown below, might defend itself.
What makes arthropods so successful? Here are some of the most obvious evolutionary advances that arthropods show over the simpler, more "primitive" mollusks and segmented worms:
Exoskeletons -- "outside skeletons" -- are one of "nature's greatest inventions" -- one of the main features responsible for arthropods being so successful. Below you can see a pillbug shedding its old exoskeleton:
Shedding takes place in two stages. First the rear end covering is shed, so in the picture the old exoskeleton is white part at the left of the darker pillbug. The dark pillbug is half covered with its old front covering, which is paler than the rest of the body. That pale covering will be shed next.
If you're a land animal wanting to move around faster than a snail or an earthworm, you need muscles and you need stiffness. Stiffness is important because muscles must be attached to something secure, and the appendages they move must be stiff, or else they'll flop and flap, instead of taking steps, or raising hands or feet. Unskeletonized flesh can artfully ripple, wiggle, and elongate and shorten, but that's nothing compared to a cockroach's ability to skitter across the kitchen floor.
Arthropod exoskeletons serve the same functions as our human skeletons, which are inside-the-body endoskeletons. The question arises, then, "If exoskeletons are so great, why don't humans, birds, fish and elephants have them?"
It happens that, because of the general physics of large and small bodies, endoskeletons work better in land animals over, say, three inches long (7.6cm), while exoskeletons are best for smaller land animals. Anyone who has seen an oversized ripe watermelon burst from being banged around too much knows how fragile rigid coverings are for large, heavy bodies. Also, it's hard to imagine a Ladybird Beetle crammed with the numbers of highly specialized bones a human has.
Moreover, exoskeletons have at least two major drawbacks, even for small animals: