2.1 DIFFERENTIATION
C
P
Q
ρθ θ+∆θ∆θxf(x)Figure 2.4 Two neighbouring tangents to the curvef(x) whose slopes differ
by ∆θ. The angular separation of the corresponding radii of the circle of
curvature is also ∆θ.pointPon the curvef=f(x), with tanθ=df/dxevaluated atP. Now consider
also the tangent at a neighbouring pointQon the curve, and suppose that it
makes an angleθ+∆θwith thex-axis, as illustrated in figure 2.4.
It follows that the corresponding normals atPandQ, which are perpendicularto the respective tangents, also intersect at an angle ∆θ. Furthermore, their point
of intersection,Cin the figure, will be the position of the centre of a circle that
approximates the arcPQ, at least to the extent of having the same tangents at
the extremities of the arc. This circle is called thecircle of curvature.
For a finite arcPQ, the lengths ofCPandCQwill not, in general, be equal,as they would be iff=f(x)werein fact the equation of a circle. But, asQ
is allowed to tend toP,i.e.as∆θ→0, they do become equal, their common
value beingρ, the radius of the circle, known as theradius of curvature. It follows
immediately that the curve and the circle of curvature have a common tangent
atPand lie on the same side of it. The reciprocal of the radius of curvature,ρ−^1 ,
defines thecurvatureof the functionf(x) at the pointP.
The radius of curvature can be defined more mathematically as follows. Thelength ∆sof arcPQis approximately equal toρ∆θand, in the limit ∆θ→0, this
relationship definesρas
ρ= lim
∆θ→ 0∆s
∆θ=ds
dθ. (2.15)
It should be noted that, assincreases,θmay increase or decrease according to
whether the curve is locally concave upwards (i.e. shaped as if it were near a
minimum inf(x)) or concave downwards. This is reflected in the sign ofρ,which
therefore also indicates the position of the curve (and of the circle of curvature)