304 B. SOME RESULTS IN COMPARISON GEOMETRY
LEMMA B.44. The functions b"f,s are uniformly bounded: for all x E Mn
ands 2: 0,lb"f,s (x)I ~ d (x, 0).
The functions b"f,s are uniformly Lipschitz with Lipschitz constant l: for all
x, y E Mn ands 2: 0,lb"f,S (x) - b"(,S (y)I ~ d (x, y).And the functions b"f,s (x) are monotone increasing ins for each x E Mn:
ifs< t, thenPROOF. All three statements are consequences of the triangle inequality.
The first is immediate, and the second follows from observationlb"f,s (x) - b"f,s (y)I = Id (y, I (s)) - d (x, I (s))I ~ d (x, y).To prove the third, we note that db (s), I (t)) = t - sand observe that
b"f,t (x) ~ t - d (x, 1 (t))
2: s + (t - s) - d (x, 1 ( s)) - db (s) , I (t))= s - d ( x, I ( s)) ~ b'Y ,s ( x).
DThe monotonicity of the pre-Busemann functions in the parameter s
enables us to make the followingDEFINITION B.45. The Busemann function b'Y : Mn___, JR. associated
to the ray I isSince the family {b'Y,s} is uniformly Lipschitz and uniformly bounded
above, we can immediately make the following observations.LEMMA B.46. The Busemann function b'Y associated to a ray 1 emanat-
ing from 0 E Mn is bounded above: for all x E Mn,(B.5) I b'Y ( x) I ~ d ( x, o).And b'Y is uniformly Lipschitz with Lipschitz constant l: for all x, y E Mn,(B.6) lb'Y (x) - b'Y (y)I ~ d (x, y).Intuitively, b'Y (x) measures how far out toward infinity x is in the direc-
tion of I · One could also regard b'Y as a renormalized distance function from
what one might think of as the 'point' r (oo). For example, in Euclidean
space, the Busemann functions are the affine projections. In particular, if