A car is parked among N cars standing i...

A car is parked among `N` cars standing in a row, but not at either end. On his return, the owner finds that exactly `"r"` of the `N` places are still occupied. The probability that the places neighboring his car are empty is a.`((r-1)!)/((N-1)!)` b. `((r-1)!(N-r)!)/((N-1)!)` c. `((N-r)(N-r-1))/((N-1)(N+2))` d. `"^((N-r)C_2)/(.^(N-1)C_2)`

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A car is parked among N cars standing in a row, but not at either end. On his return, the owner finds that exactly "r" of the N places are still occupied. The probability that the places neighboring his car are empty is ((r-1)!)/((N-1)!) b. ((r-1)!(N-r)!)/((N-1)!) c. ((N-r)(N-r-1))/((N-1)(N+2)) d. (^(N-r)C_2)/(^(N-1)C_2)

A car is parked among N cars standing in a row but not at either end. On his return, the owner finds that exactly r of the N places are still occupied. What is the probability that both the places neighbouring his car are empty?

A car is parked among N cars standing in a row, but at either end. On his return, the owner finds that exactly r of the N places are still occupied. The probability that both the places neighboring his car are empty is

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Show that , (.^(n)C_(r)+^(n)C_(r-1))/(.^(n)C_(r-1)+^(n)C_(r-2))=(.^(n+1)p_(r))/(r.^(n+1)p_(r-1))

Probability if n heads in 2n tosses of a fair coin can be given by prod_(r=1)^n((2r-1)/(2r)) b. prod_(r=1)^n((n+r)/(2r)) c. sum_(r=0)^n((^n C_r)/(2^n))^2 d. (sumr=0n(^n C_r)^2)/(sumr=0 2n(^(2n)C_r)^)

Probability if n heads in 2n tosses of a fair coin can be given by prod_(r=1)^n((2r-1)/(2r)) b. prod_(r=1)^n((n+r)/(2r)) c. sum_(r=0)^n((^n C_r)/(2^n)) d. (sumr=0n(^n C_r)^2)/(sumr=0 2n(^(2n)C_r)^)

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