product rule

(noun)

the probability of two independent events occurring together can be calculated by multiplying the individual probabilities of each event occurring alone

Related Terms

Examples of product rule in the following topics:

  • Rules of Probability for Mendelian Inheritance

    • The product rule of probability can be applied to this phenomenon of the independent transmission of characteristics.
    • The word "and" is a signal to apply the product rule.
    • Consider how the product rule is applied to a dihybrid : the probability of having both dominant traits in the F2 progeny is the product of the probabilities of having the dominant trait for each characteristic.
    • The word "or" indicates that you should apply the sum rule.
    • You should also notice that we used the product rule to calculate the probability of PH and QT and also the probability of PT and QH, before we summed them.

  • Mendel's Law of Independent Assortment

    • The sorting of alleles for texture and color are independent events, so we can apply the product rule.
    • Round/green and wrinkled/yellow offspring can also be calculated using the product rule as each of these genotypes includes one dominant and one recessive phenotype.
    • Note that this process is a diagrammatic version of the product rule.

  • Chemical Reactions and Molecules

    • According to the octet rule, elements are most stable when their outermost shell is filled with electrons.
    • An arrow is typically drawn between the reactants and products to indicate the direction of the chemical reaction.
    • In reversible reactions, reactants are turned into products, but when the concentration of product goes beyond a certain threshold, some of these products will be converted back into reactants; at this point, the designations of products and reactants are reversed.
    • This back and forth continues until a certain relative balance between reactants and products occurs: a state called equilibrium.
    • In biological reactions, however, equilibrium is rarely obtained because the concentrations of the reactants or products or both are constantly changing, often with a product of one reaction being a reactant for another.

  • Abiotic Factors Influencing Plant Growth

    • Temperature and moisture are important influences on plant production (primary productivity) and the amount of organic matter available as food (net primary productivity).
    • Almost all life on earth is directly or indirectly reliant on primary production.
    • Very productive biomes have a high level of aboveground biomass.
    • The magnitude and distribution of global primary production varies between biomes.
    • However, warm and wet climates have the greatest amount of annual biomass production.

  • Productivity within Trophic Levels

    • Productivity, measured by gross and net primary productivity, is defined as the amount of energy that is incorporated into a biomass.
    • The rate at which photosynthetic primary producers incorporate energy from the sun is called gross primary productivity.
    • An example of gross primary productivity is the compartment diagram of energy flow within the Silver Springs aquatic ecosystem .
    • The net productivity is then available to the primary consumers at the next trophic level.
    • Explain the concept of primary production and distinguish between gross primary production and net primary production

  • Early Biotechnology: Cheese, Bread, Wine, Beer, and Yogurt

    • Some of the earliest biotechnology used prokaryotes for the production of food products such as cheese, bread, wine, beer, and yogurt.
    • Cheese production began around 4,000–7,000 years ago when humans began to breed animals and process their milk.
    • Additionally, evidence suggests that cultured milk products, such as yogurt, have existed for at least 4,000 years.
    • These products use prokaryotes (as with cheese) to provide flavor and to protect the food product from other unwanted microbes.
    • Discuss the origins of food biotechnology as indicated by the production of cheese, bread, wine, beer, and yogurt

  • Production of Vaccines, Antibiotics, and Hormones

    • Biotechnological advances in gene manipulation techniques have further resulted in the production of vaccines, antibiotics, and hormones.
    • Antibiotics are biotechnological products that inhibit bacterial growth or kill bacteria.
    • Previously, it was only possible to treat diabetes with pig insulin, which caused allergic reactions in humans because of differences in the gene product.
    • The bacteria was then grown and the hormone isolated, enabling large scale commercial production.

  • Hormonal Regulation of the Reproductive System

    • In both males and females, FSH stimulates gamete production and LH stimulates production of hormones by the gonads.
    • An increase in gonad hormone levels inhibits GnRH production through a negative feedback loop .
    • FSH production is inhibited by the hormone inhibin, which is released by the testes.
    • LH stimulates production of the sex hormones (androgens) by the Leydig cells of the testes.
    • Prolactin stimulates the production of milk by the mammary glands, following childbirth.

  • Pineal Gland and Gonads

    • The pineal gland is responsible for melatonin production, while the gonads secrete hormones relating to sexual characteristic development.
    • The rate of melatonin production is affected by the photoperiod.
    • During the day photoperiod, little melatonin is produced; however, melatonin production increases during the dark photoperiod (night).
    • Their main role is the production of steroid hormones.
    • The testes produce androgens, which allow for the development of secondary sex characteristics and the production of sperm cells.

  • Speciation

    • There are exceptions to this rule.
    • Many species are similar enough that hybrid offspring are possible and may often occur in nature, but for the majority of species this rule generally holds.