frequency-dependent selection

(noun)

the term given to an evolutionary process where the fitness of a phenotype is dependent on its frequency relative to other phenotypes in a given population

Related Terms

Examples of frequency-dependent selection in the following topics:

  • Frequency-Dependent Selection

    • In frequency-dependent selection, phenotypes that are either common or rare are favored through natural selection.
    • Another type of selection, called frequency-dependent selection, favors phenotypes that are either common (positive frequency-dependent selection) or rare (negative frequency-dependent selection).
    • Negative frequency-dependent selection serves to increase the population's genetic variance by selecting for rare phenotypes, whereas positive frequency-dependent selection usually decreases genetic variance by selecting for common phenotypes.
    • Positive frequency-dependent selection reinforces the common phenotype because predators avoid the distinct coloration.
    • Frequency-dependent selection allows for both common and rare phenotypes of the population to appear in a frequency-aided cycle.

  • Natural Selection and Adaptive Evolution

    • Natural selection drives adaptive evolution by selecting for and increasing the occurrence of beneficial traits in a population.
    • Natural selection only acts on the population's heritable traits: selecting for beneficial alleles and, thus, increasing their frequency in the population, while selecting against deleterious alleles and, thereby, decreasing their frequency.
    • Natural selection does not act on individual alleles, however, but on entire organisms.
    • As natural selection influences the allele frequencies in a population, individuals can either become more or less genetically similar and the phenotypes displayed can become more similar or more disparate.
    • Through natural selection, a population of finches evolved into three separate species by adapting to several difference selection pressures.

  • Forced Vibrations and Resonance

    • The phenomenon of driving a system with a frequency equal to its natural frequency is called resonance.
    • The phenomenon of driving a system with a frequency equal to its natural frequency is called resonance.
    • It is interesting that the widths of the resonance curves shown in depend on damping: the less the damping, the narrower the resonance.
    • The more selective the radio is in discriminating between stations, the smaller its damping.
    • Resonance occurs when the driving frequency equals the natural frequency, and the greatest response is for the least amount of damping.

  • Frequency of Sound Waves

    • The perception of frequency is called pitch.
    • The perception of frequency is called pitch.
    • Frequency is dependent on wavelength and the speed of sound.
    • Different species can hear different frequency ranges.
    • Three flashing lights, from lowest frequency (top) to highest frequency (bottom). f is the frequency in hertz (Hz); or the number of cycles per second.

  • Guidelines for Plotting Frequency Distributions

    • In statistics, the frequency (or absolute frequency) of an event is the number of times the event occurred in an experiment or study.
    • These frequencies are often graphically represented in histograms.
    • The relative frequency (or empirical probability) of an event refers to the absolute frequency normalized by the total number of events.
    • The height of a rectangle is also equal to the frequency density of the interval, i.e., the frequency divided by the width of the interval.
    • Depending on the actual data distribution and the goals of the analysis, different bin widths may be appropriate, so experimentation is usually needed to determine an appropriate width.

  • The Photoelectric Effect

    • The energy of the emitted electrons does not depend on the intensity of the incoming light (the number of photons), only on the energy or frequency of the individual photons.
    • This frequency is called the threshold frequency.
    • where h is the Planck constant (6.626 x 10-34 m2kg/s) and f is the frequency of the incident photon.
    • where f0 is the threshold frequency for the metal.
    • The photocathode contains combinations of materials, such as caesium, rubidium, and antimony, specially selected to provide a low work function, so when illuminated by even very low levels of light, the photocathode readily releases electrons.

  • RLC Series Circuit: At Large and Small Frequencies; Phasor Diagram

    • Response of an RLC circuit depends on the driving frequency—at large enough frequencies, inductive (capacitive) term dominates.
    • Now, we will examine the system's response at limits of large and small frequencies.
    • At large enough frequencies $(\nu \gg \frac{1}{\sqrt{2\pi LC}})$, XL is much greater than XC.
    • The impedance Z at small frequencies $(\nu \ll \frac{1}{\sqrt{2\pi LC}})$ is dominated by the capacitive term, assuming that the frequency is high enough so that XC is much larger than R.
    • Distinguish behavior of RLC series circuits as large and small frequencies

  • Structure of the Chi-Squared Test

    • The chi-square test is used to determine if a distribution of observed frequencies differs from the theoretical expected frequencies.
    • The chi-square ($\chi^2$) test is a nonparametric statistical technique used to determine if a distribution of observed frequencies differs from the theoretical expected frequencies.
    • Thus, instead of using means and variances, this test uses frequencies.
    • Simple random sample – The sample data is a random sampling from a fixed distribution or population where each member of the population has an equal probability of selection.
    • The chi-square distribution takes slightly different shapes depending on how many categories (degrees of freedom) our variables have.

  • Resonance in RLC Circuits

    • Frequencies at which the response amplitude is a relative maximum are known as the system's resonance frequencies.
    • The reactances vary with frequency $\nu$, with XL large at high frequencies and XC large at low frequencies given as:
    • $\nu_0$ is the resonant frequency of an RLC series circuit.
    • A variable capacitor is often used to adjust the resonance frequency to receive a desired frequency and to reject others. is a graph of current as a function of frequency, illustrating a resonant peak in Irms at $\nu_0 = f_0$.
    • Thus higher-resistance circuits do not resonate as strongly, nor would they be as selective in, for example, a radio receiver.

  • Hardy-Weinberg Principle of Equilibrium

    • We can also write this as p + q = 1.If the frequency of the Y allele in the population is 0.6, then we know that the frequency of the y allele is 0.4.
    • From the Hardy-Weinberg principle and the known allele frequencies, we can also infer the frequencies of the genotypes.
    • The frequency of homozygous pp individuals is p2; the frequency of hereozygous pq individuals is 2pq; and the frequency of homozygous qq individuals is q2.
    • The frequency of heterozygous plants (2pq) is 2(0.6)(0.4) = 0.48.
    • The genetic variation of natural populations is constantly changing from genetic drift, mutation, migration, and natural and sexual selection.