uniformly placed geophones - meaning and definition. What is uniformly placed geophones
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What (who) is uniformly placed geophones - definition

SEQUENCE FUNCTION
Uniformly cauchy; Uniformly Cauchy

Uniformly convex space         
REFLEXIVE BANACH SPACE SUCH THAT THE CENTER OF A LINE SEGMENT INSIDE THE UNIT BALL MUST LIE DEEP INSIDE THE UNIT BALL UNLESS THE SEGMENT IS SHORT
Uniformly convex Banach space; Uniformly convex banach space; Uniform Convexity; Uniform convexity; Uniformly convex
In mathematics, uniformly convex spaces (or uniformly rotund spaces) are common examples of reflexive Banach spaces. The concept of uniform convexity was first introduced by James A.
Uniformly Cauchy sequence         
In mathematics, a sequence of functions \{f_{n}\} from a set S to a metric space M is said to be uniformly Cauchy if:
Uniformly connected space         
TYPE OF UNIFORM SPACE
Uniform connectedness; Cantor connectendess; Uniformly connected; Uniformly disconnected
In topology and related areas of mathematics a uniformly connected space or Cantor connected space is a uniform space U such that every uniformly continuous function from U to a discrete uniform space is constant.

Wikipedia

Uniformly Cauchy sequence

In mathematics, a sequence of functions { f n } {\displaystyle \{f_{n}\}} from a set S to a metric space M is said to be uniformly Cauchy if:

  • For all ε > 0 {\displaystyle \varepsilon >0} , there exists N > 0 {\displaystyle N>0} such that for all x S {\displaystyle x\in S} : d ( f n ( x ) , f m ( x ) ) < ε {\displaystyle d(f_{n}(x),f_{m}(x))<\varepsilon } whenever m , n > N {\displaystyle m,n>N} .

Another way of saying this is that d u ( f n , f m ) 0 {\displaystyle d_{u}(f_{n},f_{m})\to 0} as m , n {\displaystyle m,n\to \infty } , where the uniform distance d u {\displaystyle d_{u}} between two functions is defined by

d u ( f , g ) := sup x S d ( f ( x ) , g ( x ) ) . {\displaystyle d_{u}(f,g):=\sup _{x\in S}d(f(x),g(x)).}