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Assume that in a subway station trains arrive at the platform with random interarrival time, exponentially distributed, on average every 10 minutes. We visit the platform everyday at 12:00. On average, we have to wait 5 minutes for the train. inizia ad imparare
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Assume that in a queue with a finite buffer the loss ration is 0.01, the burst ratio is 2. In such a case, the average length of the series of consecutive losses is slightly smaller than 2. inizia ad imparare
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Assume that in a queue with an infinite buffer (no losses), the arrival system is Poisson, the service time is uniform. In such a case, the output process is Poisson. inizia ad imparare
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Assume that the transition matrix of a discrete-time Markov chain is [0.2 0 0.8 1]. This Markov chain is irreducible. inizia ad imparare
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Assume that the transition matrix of a discrete-time Markov chain is [1 0.5 0 0.5]. The period of this chain equals 2. inizia ad imparare
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Assume we have a discrete-time Markov chain: X0, X1, X2, X3, ... The subsequence X0, X3, X6, X9, ... is a discrete-time Markov chain inizia ad imparare
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FES is an acronym from Forward Entrance System inizia ad imparare
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FES is an acronym from Future Event Set inizia ad imparare
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If the interarrival time distribution is exponential then the steady-state queue size distribution is the same as queue size distribution observed by arriving jobs inizia ad imparare
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In a queueing system the real, unknown probability of the queue size 30 is equal to 1.2345678910-6. Finding this probability with the six-digit precision, i.e. 1.2345610-6, requires more than 108 measurements of the queue size inizia ad imparare
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In a queueing system with a finite buffer it holds: X=(1-L)R inizia ad imparare
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In a queueing system with a finite buffer it is possible to compute the burst ratio, if we know only the loss ratio and the buffer size inizia ad imparare
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In a queueing system with a finite buffer it is possible to compute the empty system probability, if we know only the system load and the loss ratio. inizia ad imparare
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In a queueing system with a finite buffer the service time is constant and equal to 2. The duration of the buffer overflow period may be 1 in this system inizia ad imparare
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In a queueing system with a finite buffer the service time is constant and equal to 10. The duration of the buffer overflow period may be 15 in this system inizia ad imparare
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In a queueing system with losses it holds: L=1-(1-pn/p) inizia ad imparare
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In a queueing system with no losses, the average queue size is equal to the arrival rate multiplied by the average response time. inizia ad imparare
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In a queueing system with Poisson arrivals the average queue size distribution observed at arbitrary times is the same as when observed at arrival times. inizia ad imparare
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In an open Jackson network, for every queue it holds: Xi=(1-p)/p inizia ad imparare
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In every queueing system with a finite buffer, the loss ratio is equal to the full-buffer probability: L=pN inizia ad imparare
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In some queueing systems the distribution of the waiting time can be the same as the distribution of the virtual waiting time inizia ad imparare
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In some queueing systems with a finite buffer, the loss ratio is equal to the full-buffer probability: L=pN inizia ad imparare
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In the M/M/1 queueing system it holds: X=(1-p)/p inizia ad imparare
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Merging two Poisson processes of rates lambda1 and lambda2, respectively, creates another Poisson process of rate lambda1+lambda2 inizia ad imparare
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Method empty() is used to remove all jobs from the queue inizia ad imparare
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Method front() adds a message at the beginning of the queue inizia ad imparare
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Method setNumCells() sets the maximum allowed queue size in a cQueue object inizia ad imparare
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Method scheduleAt() is used to schedule a message in the past inizia ad imparare
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simtime_t is a function returning the current simulated time inizia ad imparare
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The loss ratio may be equal to the full-buffer probability (i.e. the probability that queue size is N) inizia ad imparare
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The queue size distribution observed just before arrival times is the same as the queue size distribution observed just after departure times. inizia ad imparare
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The steady-state queue size distribution depends on the variance of the service time inizia ad imparare
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The system response time is the sum of the waiting time and the service time of a job inizia ad imparare
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The uniform distribution has the memoryless property inizia ad imparare
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The waiting time distribution is always the same as the virtual waiting time distribution inizia ad imparare
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Waiting distribution is always the same as the virtual waiting time distribution inizia ad imparare
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