A phenotypic "blending" of two traits is referred to as incomplete dominance, indicating that neither trait is truly dominant over the other. Instead of one color overpowering expression of the other, both colors are expressed simultaneously.

Codominance suggests that both phenotypes are dominant, but cannot be expressed at the same time. The result of codominance would be regions of dominant red expression and regions of dominant white expression, resulting in spots rather than blending.

The genotypes of the offspring can be determined by crossing the red flowers, RR, with the white flowers, rr.

RR x rr

Offspring: all offspring are Rr.

Incomplete dominance means that neither color shows dominance in the hybrid generation. This means that instead of solid red or solid white flowers, the heterozygous plants will display a mixture of both colors. Since the entire first generation will be heterozygous for the color trait, they will all be pink (a mix of white and red).

Codominance means that more than one type of dominant allele for the same gene is present. If both black and white fur are dominant, then heterozygous (Aa) offspring would be spotted with black and white.

Note this is a different expression pattern from incomplete dominance, in which a blending of phenotypes occurs.

Incomplete dominance is when more than one type of dominant allele for the same gene is present. If black and brown alleles are incompletely dominant, they "compete" for expression, which produces offspring with a combination of the two colors.

Note that this pattern difference from codominance, in which the phenotypes will be present in separate spots of blotches.

The possible genotypes for this trait are RR, Rr, and rr. To determine the answer, we must find the phenotype that corresponds to each genotype.

We know that RR is red and rr is white, since these genotypes are homozygous.

Now you must determine if Rr is red, white, or some other phenotype. Codominance means that both phenotypes show simultaneously, so the heterozygote would be both red and white, which is a distinct third phenotype. These organisms would show spots or splotches of each color.

This gives three total phenotypes: red, white, and red-white spotted.

A pink phenotype would only show in instances of incomplete dominance. When an organism is heterozygous for alleles that show incomplete dominance, an intermediate of blended phenotype will be seen.

In the species the entire range of phenotypes will be expressed. Diploid organisms have two alleles of each gene, so the plant could be homozygous for any of the alleles or it could have any heterozygous combinations.

First, we can identify three homozygous phenotypes: YY is yellow, BB is blue, and RR is red.

Now we need to identify the heterozygous phenotypes. Since the alleles show incomplete dominance, these phenotypes will be blended. YB will be green, YR will be orange, and BR will be purple.

This gives a total of six possible allele combinations and six different phenotypes.

Codominance is evidenced when the phenotypes of both parents show up in the offspring. A dog that has fur that consists of colors of both parents will be an example of codominance. Only one trait can be expressed at a time, since they are both dominant phenotypes. This results in regions of one dominant allele and regions of the other, showing a spotted or mottled pattern.

Incomplete dominance occurs when neither trait is truly dominant over the other. This means that both traits can be expressed in the same regions, resulting a blending of two phenotypes. If a white and black dog produce a gray offspring, this is an example of incomplete dominance.

The answer that suggests a red offspring from a black parent and tan parent could result from one of two scenarios. The first possibility is that there are three alleles for color, with red recessive to both black and tan. Both parents carry the red allele, but do not display it, and then pass it to the offspring. Something similar happens with the O blood type. The other possibility is that red color is a new mutation.

In the example above, the flower has both red and white petals due to co-dominant inheritance pattern of the red and white petal alleles. If the flower’s phenotype was determined by incomplete dominance, the F1 hybrids would be in-between the parental phenotypes (i.e. if a red petal parent was crossed with a white petal parent, then the F1 generation would be pink). Polygenic inheritance occurs when two or more genes control one characteristic, such as skin color, eye color, and adult height. 

Incomplete dominance is described by a phenotype that is not completely dominant over another. Therefore, it will be a "blending" of colors in the case of this question, therefore the petals are pink. Codominance is when both dominant traits are expressed, therefore if white was considered dominant and red was also a dominant trait, the petals would have spots of white and red, with no pink. Polygenic inheritance is described by one characteristic influenced by multiple genes, which is not the case in this problem. Finally, epistasis involves the suppression of genes, however in this problem color is not suppressed.