R is drawn first because it's fast acting
There are several different names for regular insulin, depending on the maker. The one constant is that all of them contain the letter "R" for "regular," in their name. For instance, one maker of insulin called all their insulins Novolin. The "regular" insulin is "Novolin R," their NPH is called "Novolin N," etc.
a+a*r+a*r^2+...+a*r^n a = first number r = ratio n = "number of terms"-1
n p =n!/(n-r)! r and n c =n!/r!(n-r)! r
This browser is totally bloody useless for mathematical display but...The probability function of the binomial distribution is P(X = r) = (nCr)*p^r*(1-p)^(n-r) where nCr =n!/[r!(n-r)!]Let n -> infinity while np = L, a constant, so that p = L/nthenP(X = r) = lim as n -> infinity of n*(n-1)*...*(n-k+1)/r! * (L/n)^r * (1 - L/n)^(n-r)= lim as n -> infinity of {n^r - O[(n)^(k-1)]}/r! * (L^r/n^r) * (1 - L/n)^(n-r)= lim as n -> infinity of 1/r! * (L^r) * (1 - L/n)^(n-r) (cancelling out n^r and removing O(n)^(r-1) as being insignificantly smaller than the denominator, n^r)= lim as n -> infinity of (L^r) / r! * (1 - L/n)^(n-r)Now lim n -> infinity of (1 - L/n)^n = e^(-L)and lim n -> infinity of (1 - L/n)^r = lim (1 - 0)^r = 1lim as n -> infinity of (1 - L/n)^(n-r) = e^(-L)So P(X = r) = L^r * e^(-L)/r! which is the probability function of the Poisson distribution with parameter L.
Geometric series may be defined in terms of the common ratio, r, and either the zeroth term, a(0), or the first term, a(1).Accordingly,a(n) = a(0) * r^n ora(n) = a(1) * r^(n-1)
There are several different names for regular insulin, depending on the maker. The one constant is that all of them contain the letter "R" for "regular," in their name. For instance, one maker of insulin called all their insulins Novolin. The "regular" insulin is "Novolin R," their NPH is called "Novolin N," etc.
28989675, based on the following criteria: Combination means order does not matter, and there is no repetition allowed (like drawing lotto balls, once a number is drawn, then it cannot be drawn again, and order that the balls are drawn doesn't matter) The formula for this is Combination of n items, taken rat a time.C(n,r) = n! / (r!(n-r)!), where n = 55 and r = 6, in this case. See related link on MathsIsFun.com
Drawn Together - 2004 N-R-A vs- Ray 3-5 was released on: USA: 1 November 2006 Australia: 30 July 2007
a+a*r+a*r^2+...+a*r^n a = first number r = ratio n = "number of terms"-1
I am from The United States other country's may have different laws. Insulin is sold over the counter due to the fact that people with Diabetes don't always have a prescription for the medicine yet they still need to take it to live. In my area these insulin's range in price from $40-$60 There is a list of insulin sold over the counter such as Novolin N, Novolin R, Novolin 70/30, Humulin N, Humulin R, Humulin 70/30, Humulin 50/50and so on. There is a list of insulin NOT SOLD OVER THE COUNTER. Apidra, lantus, Novolog, Humalog ect. So in fact it would be murder if you could not purchase insulin over the counter. Although if you have no money and you need insulin it would seem that you might be out of luck or life.
nCr + nCr-1 = n!/[r!(n-r)!] + n!/[(r-1)!(n-r+1)!] = n!/[(r-1)!(n-r)!]*{1/r + 1/n-r+1} = n!/[(r-1)!(n-r)!]*{[(n-r+1) + r]/[r*(n-r+1)]} = n!/[(r-1)!(n-r)!]*{(n+1)/r*(n-r+1)]} = (n+1)!/[r!(n+1-r)!] = n+1Cr
N. R. Tostevin has written: 'The first great seal of Charles II at Sausmarez'
n p =n!/(n-r)! r and n c =n!/r!(n-r)! r
If the first term, t(1) = a and the common difference is r then t(n) = a + (n-1)*r where n = 1, 2, 3, ...
This browser is totally bloody useless for mathematical display but...The probability function of the binomial distribution is P(X = r) = (nCr)*p^r*(1-p)^(n-r) where nCr =n!/[r!(n-r)!]Let n -> infinity while np = L, a constant, so that p = L/nthenP(X = r) = lim as n -> infinity of n*(n-1)*...*(n-k+1)/r! * (L/n)^r * (1 - L/n)^(n-r)= lim as n -> infinity of {n^r - O[(n)^(k-1)]}/r! * (L^r/n^r) * (1 - L/n)^(n-r)= lim as n -> infinity of 1/r! * (L^r) * (1 - L/n)^(n-r) (cancelling out n^r and removing O(n)^(r-1) as being insignificantly smaller than the denominator, n^r)= lim as n -> infinity of (L^r) / r! * (1 - L/n)^(n-r)Now lim n -> infinity of (1 - L/n)^n = e^(-L)and lim n -> infinity of (1 - L/n)^r = lim (1 - 0)^r = 1lim as n -> infinity of (1 - L/n)^(n-r) = e^(-L)So P(X = r) = L^r * e^(-L)/r! which is the probability function of the Poisson distribution with parameter L.
Geometric series may be defined in terms of the common ratio, r, and either the zeroth term, a(0), or the first term, a(1).Accordingly,a(n) = a(0) * r^n ora(n) = a(1) * r^(n-1)
The difference between successive terms in an arithmetic sequence is a constant. Denote this by r. Suppose the first term is a. Then the nth term, of the sequence is given by t(n) = (a-r) + n*r or a + (n-1)*r