The same species in the same area at the same time. Also, a unit of evolution.

The same species in the same area through evolutionary time. Also, a unit of evolution.

The same species, regardless of geographical location, occurring at the same time. Also, a unit of evolution.

Many species occurring in the same place, at the same time. Also, a unit of evolution.

The Amphibian decline, which is a consequence of human impact on their natural environment.

The Amphibian decline, which is a consequence of human impact, along with over-population of humans and climate change.

The Amphibian decline, which is a result of pollution, invasive species and habitat loss, largely due to human impact - along with over-population of humans and climate change.

Demography refers to influences on size and structure of a population (births/deaths, immigration/emmigration) over time.
I. Survivorship plummets at young age
II. Steady
III. Survivorship plummets at old age

Demography refers to influences on size and structure of a population (births/deaths, immigration/emmigration) over time.
I. Survivorship plummets at old age
II. Steady
III. Survivorship plummets at young age

I. Survivorship plummets at old age (humans)
II. Steady, specialized predators at each life stage (sea turtles, plants, fish)
III. Survivorship plummets at young age (songbirds)

I. Survivorship plummets at old age (humans)
II. Steady, specialized predators at each life stage (songbirds)
III. Survivorship plummets at young age (sea turtles, plants, fish)

To choose which ecosystems should be preserved according to their impact on the biosphere.

To choose between the preservation of certain species, depending on their impact on humans.

To provide protection for high survivorship (or "life history") stages of species.

To provide protection for low survivorship (or "life history") stages of species.

To provide protection for low survivorship (or "life history") stages in endangered species.

A life table of individuals in a population can predict the rates of survivorship and fecundity in a species, determining the average number of female offspring produced by each female and where the species lies on the life history continuum.

A life table of individuals in a population can predict the rates of fecundity in a species, determining the average number of female offspring produced by each female and where the species lies on the life history continuum.

A life table of individuals in a population can predict the rates of survivorship in a species, determining the average number of female offspring produced by each female and where the species lies on the life history continuum.

A life table of individuals in a population can predict the rates of female offspring produced by each female, determining the fecundity and survivorship of the species and where it lies on the life history continuum.

Intermediate refers to the average survivorship and amount of offspring produced. It is proven to be the most adaptive life history trait.

Intermediate refers to average survivorship and fecundity being between the rates in France and Austria. It proves that there are fitness trade offs between survivorship and fecundity of a species.

Intermediate refers to the average amount of female offspring produced, according to rates of survivorship and fecundity, being between those of France and Austria. It proves that intermediate amounts of female offspring produced is the most adaptive life history trait.

Intermediate refers to the rates of survivorship and fecundity being equal in the Netherlands species, allowing the species to live as long as possible while reproducing as much as possible. This is proven to be the most adaptive life history trait.

Low fecundity/high survivorship - Elephants
Moderate - L. vivipara (Netherlands)
High fecundity/low survivorship - Sea turtles

Low fecundity/high survivorship - Sea turtles
Moderate - L. vivipara (Netherlands)
High fecundity/low survivorship - Elephants

Hypothesis: Through evolutionary time, alleles may change in frequency for larger body size/greater age of sexual maturity in guppies of Trinidad. Experimental group: Guppies from upstream (low predation) were placed downstream (high predation). Control: Guppies from downstream (high predation) were placed in a different downstream (high predation) pool.

Hypothesis: Through evolutionary time, alleles may change in frequency for larger body size/greater age of sexual maturity in guppies of Trinidad. Experimental group: Guppies from downstream (high predation) were placed upstream (low predation). Control: Guppies from downstream (high predation) were placed in a different downstream (high predation) pool.

Hypothesis: Through evolutionary time, alleles may change in frequency for larger body size/greater age of sexual maturity in guppies of Trinidad. Experimental group: Guppies from upstream (low predation) were placed in another upstream (low predation) pool. Control: Guppies from downstream (high predation) were placed in an upstream (low predation) pool.

Hypothesis: Through evolutionary time, alleles may change in frequency for larger body size/greater age of sexual maturity in guppies of Trinidad. Experimental group: Guppies from downstream (high predation) were placed upstream (low predation). Control: Guppies from upstream (low predation) were placed in a different upstream (low predation) pool.