`=>`As we know, If a directed line `L` passing through the origin makes angles `α, β` and `γ` with `x, y` and `z-`axes, respectively, called direction angles, then cosine of these angles, namely, `cos α, cos β` and `cos γ` are called direction cosines of the directed line `L.`
`=>` If we reverse the direction of `L,` then the direction angles are replaced by their supplements,
i.e., `π −α , π − β` and `π − γ.` Thus, the signs of the direction cosines are reversed.
`color{blue}{"Direction Ratios : "}` Any three numbers which are proportional to the direction cosines of a line are called the direction ratios of the line. If `l, m, n` are direction cosines and `a, b, c` are direction ratios of a line, then `a = λl, b=λm` and `c = λn,` for any nonzero `λ ∈ R.`
`"Note -"` Some authors also call direction ratios as direction numbers.
● Let `a, b, c` be direction ratios of a line and let `l, m` and `n` be the direction cosines (d.c’s) of the line. Then
`l/a = m/b = n/c = k` (say), k being a constant.
Therefore` l = ak, m = bk, n = ck` ... (1)
But `l^2 + m^2 + n^2 = 1`
Therefore `k^2 (a^2 + b^2 + c^2) = 1`
or ` k = pm (1)/( sqrt (a^2 + b^2 + c^2 ) )`
Hence, from (1), the d.c.’s of the line are
`color{red}{ l = pm a/(sqrt (a^2 + b^2 + c^2 ) ) , m = pm b/(sqrt (a^2 + b^2 + c^2 ) ) , n = pm c/(sqrt (a^2 + b^2 + c^2) )}`
`=>` where, depending on the desired sign of k, either a positive or a negative sign is to be taken for l, m and n.
`=>` For any line, if a, b, c are direction ratios of a line, then `ka, kb, kc; k ≠ 0` is also a set of direction ratios. So, any two sets of direction ratios of a line are also proportional.
`=>` Also, for any line there are infinitely many sets of direction ratios.
`=>`As we know, If a directed line `L` passing through the origin makes angles `α, β` and `γ` with `x, y` and `z-`axes, respectively, called direction angles, then cosine of these angles, namely, `cos α, cos β` and `cos γ` are called direction cosines of the directed line `L.`
`=>` If we reverse the direction of `L,` then the direction angles are replaced by their supplements,
i.e., `π −α , π − β` and `π − γ.` Thus, the signs of the direction cosines are reversed.
`color{blue}{"Direction Ratios : "}` Any three numbers which are proportional to the direction cosines of a line are called the direction ratios of the line. If `l, m, n` are direction cosines and `a, b, c` are direction ratios of a line, then `a = λl, b=λm` and `c = λn,` for any nonzero `λ ∈ R.`
`"Note -"` Some authors also call direction ratios as direction numbers.
● Let `a, b, c` be direction ratios of a line and let `l, m` and `n` be the direction cosines (d.c’s) of the line. Then
`l/a = m/b = n/c = k` (say), k being a constant.
Therefore` l = ak, m = bk, n = ck` ... (1)
But `l^2 + m^2 + n^2 = 1`
Therefore `k^2 (a^2 + b^2 + c^2) = 1`
or ` k = pm (1)/( sqrt (a^2 + b^2 + c^2 ) )`
Hence, from (1), the d.c.’s of the line are
`color{red}{ l = pm a/(sqrt (a^2 + b^2 + c^2 ) ) , m = pm b/(sqrt (a^2 + b^2 + c^2 ) ) , n = pm c/(sqrt (a^2 + b^2 + c^2) )}`
`=>` where, depending on the desired sign of k, either a positive or a negative sign is to be taken for l, m and n.
`=>` For any line, if a, b, c are direction ratios of a line, then `ka, kb, kc; k ≠ 0` is also a set of direction ratios. So, any two sets of direction ratios of a line are also proportional.
`=>` Also, for any line there are infinitely many sets of direction ratios.