Legendre transforms 17x
x 0slope = f ’(x 0 )f(x) + cf(x)Fig. 1.6Depiction of the Legendre transform.clear, is thats 0 , being the slope of the line tangent tof(x) atx 0 , is also the slope
off(x) +catx=x 0 for any constantc. Thus,f(x 0 ) cannot be uniquely determined
froms 0. However, if we specify both the slope,s 0 =f′(x 0 ), and they-intercept,b(x 0 ),
of the line tangent to the function atx 0 , thenf(x 0 ) can be uniquely determined. In
fact,f(x 0 ) will be given by the equation of the line tangent to the function atx 0 :
f(x 0 ) =f′(x 0 )x 0 +b(x 0 ). (1.5.2)Eqn. (1.5.2) shows how we may transform from a description off(x) in terms ofxto
a new description in terms ofs. First, since eqn. (1.5.2) is valid for allx 0 , it can be
written generally in terms ofxas
f(x) =f′(x)x+b(x). (1.5.3)Then, recognizing thatf′(x) =g(x) =sandx=g−^1 (s), and assuming thats=g(x)
exists and is a one-to-one mapping, it is clear that the functionb(g−^1 (s)), given by
b(g−^1 (s)) =f(g−^1 (s))−sg−^1 (s), (1.5.4)contains the same information as the originalf(x) but expressed as a function ofs
instead ofx. We call the functionf ̃(s) =b(g−^1 (s)) theLegendre transformoff(x).
The functionf ̃(s) can be written compactly as
f ̃(s) =f(x(s))−sx(s), (1.5.5)wherex(s) serves to remind us thatxis a function ofsthrough the variable transfor-
mationx=g−^1 (s).