Distance bounds for high dimensional consistent digital rays and 2-D partially-consistent digital rays

Abstract: We consider the problem of digitalizing Euclidean segments. Specifically, we look for a constructive method to connect any two points in Z d . The construction must be consistent (that is, satisfy the natural extension of the Euclidean axioms) while resembling them as much as possible. Previous work has shown asymptotically tight results in two dimensions with Θ(log N ) error, where resemblance between segments is measured with the Hausdorff distance, and N is the L1 distance between the two points. This const… Show more

“…This implies that the slope of ℓ(r) would need to be less than 1 in order for r d−1 to be above or on q. However, Lemma 7 states that M (ℓ(r)) > 3 3−2δ > 1. It follows that r d−1 is below q and therefore r d−1 x − p ← x > 1.5 − δ.…”

“…Indeed, 24.57−236.16(0.1)+140.58(0.1) 2 +22.86(0.1) 3 = 2.38266. Thus M (p) > 3 3−2δ for all p ∈ P which implies that for every p ∈ Subtree(s) it must be that M (p) > 3 3−2δ . Next we will show that M (p) < 1 + 4δ 3−2δ = 3+2δ 3−2δ for every point p that is 3 above ℓ(t) such that N ′′ ≤ D(p) < N ′ .…”

“…They also consider what is the minimum number of inner leaves needed to obtain a WCDR with error e. In the full version of their paper [3], they give a system with error 2.5 under the L ∞ metric establishing that O(1) error is in fact possible. Note that their Ω( N log N N +k ) lower bound implies that k ∈ Ω(N log N ) in order to achieve O(1) error, but their construction has k ∈ Θ(N 2 ).…”

“…Given a fixed M (s), we can see that M (h) grows as D(s) becomes larger. Recall that M (s) > 3 3−2δ and D(s) ≥ N ′′ . It follows that M (h) is at least the slope of the point, q, that is 1.5 diagonal distance below Inter(ℓ(3 − 2δ, 3), N ′′ ).…”

“…Figure13 An illustration of P under ℓ(r). The Euclidean line with slope3 3−2δ is represented by the purple line on the bottom.…”

Optimal Bounds for Weak Consistent Digital Rays in 2D

“…This implies that the slope of ℓ(r) would need to be less than 1 in order for r d−1 to be above or on q. However, Lemma 7 states that M (ℓ(r)) > 3 3−2δ > 1. It follows that r d−1 is below q and therefore r d−1 x − p ← x > 1.5 − δ.…”

“…Indeed, 24.57−236.16(0.1)+140.58(0.1) 2 +22.86(0.1) 3 = 2.38266. Thus M (p) > 3 3−2δ for all p ∈ P which implies that for every p ∈ Subtree(s) it must be that M (p) > 3 3−2δ . Next we will show that M (p) < 1 + 4δ 3−2δ = 3+2δ 3−2δ for every point p that is 3 above ℓ(t) such that N ′′ ≤ D(p) < N ′ .…”

“…They also consider what is the minimum number of inner leaves needed to obtain a WCDR with error e. In the full version of their paper [3], they give a system with error 2.5 under the L ∞ metric establishing that O(1) error is in fact possible. Note that their Ω( N log N N +k ) lower bound implies that k ∈ Ω(N log N ) in order to achieve O(1) error, but their construction has k ∈ Θ(N 2 ).…”

“…Given a fixed M (s), we can see that M (h) grows as D(s) becomes larger. Recall that M (s) > 3 3−2δ and D(s) ≥ N ′′ . It follows that M (h) is at least the slope of the point, q, that is 1.5 diagonal distance below Inter(ℓ(3 − 2δ, 3), N ′′ ).…”

“…Figure13 An illustration of P under ℓ(r). The Euclidean line with slope3 3−2δ is represented by the purple line on the bottom.…”

Optimal Bounds for Weak Consistent Digital Rays in 2D