Difference between revisions of "Theory of Stochastic Signals/Binomial Distribution"
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To derive the binomial distribution, we assume that $I$ binary and statistically independent random variables $b_i$ each can achieve | To derive the binomial distribution, we assume that $I$ binary and statistically independent random variables $b_i$ each can achieve | ||
*the value $1$ with probability ${\rm Pr}(b_i = 1) = p$, and | *the value $1$ with probability ${\rm Pr}(b_i = 1) = p$, and | ||
| + | |||
*the value $0$ with probability ${\rm Pr}(b_i = 0) = 1-p$. | *the value $0$ with probability ${\rm Pr}(b_i = 0) = 1-p$. | ||
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<br> | <br> | ||
{{BlaueBox|TEXT= | {{BlaueBox|TEXT= | ||
| − | $\text{Calculation rule:}$ | + | $\text{Calculation rule:}$ For the »'''probabilities of the binomial distribution'''« with $μ = 0, \hspace{0.1cm}\text{...} \hspace{0.1cm}, \ I$: |
| − | For the »'''probabilities of the binomial distribution'''« with $μ = 0, \hspace{0.1cm}\text{...} \hspace{0.1cm}, \ I$: | ||
:$$p_\mu = {\rm Pr}(z=\mu)={I \choose \mu}\cdot p\hspace{0.05cm}^\mu\cdot ({\rm 1}-p)\hspace{0.05cm}^{I-\mu}.$$ | :$$p_\mu = {\rm Pr}(z=\mu)={I \choose \mu}\cdot p\hspace{0.05cm}^\mu\cdot ({\rm 1}-p)\hspace{0.05cm}^{I-\mu}.$$ | ||
| − | + | The first term here indicates the number of combinations $($read: $I\ \text{ over }\ μ)$: | |
:$${I \choose \mu}=\frac{I !}{\mu !\cdot (I-\mu) !}=\frac{ {I\cdot (I- 1) \cdot \ \cdots \ \cdot (I-\mu+ 1)} }{ 1\cdot 2\cdot \ \cdots \ \cdot \mu}.$$}} | :$${I \choose \mu}=\frac{I !}{\mu !\cdot (I-\mu) !}=\frac{ {I\cdot (I- 1) \cdot \ \cdots \ \cdot (I-\mu+ 1)} }{ 1\cdot 2\cdot \ \cdots \ \cdot \mu}.$$}} | ||
| − | Additional notes: | + | $\text{Additional notes:}$ |
| − | + | #For very large values of $I$, the binomial distribution can be approximated by the [[Theory_of_Stochastic_Signals/Poisson_Distribution|»Poisson distribution«]] described in the next section. | |
| − | + | #If at the same time the product $I · p \gg 1$, then according to [https://en.wikipedia.org/wiki/De_Moivre%E2%80%93Laplace_theorem »de Moivre–Laplace's $($central limit$)$ theorem«], the Poisson distribution $($and hence the binomial distribution$)$ transitions to a discrete [[Theory_of_Stochastic_Signals/Gaussian_Distributed_Random_Variables|»Gaussian distribution«]]. | |
| − | {{GraueBox|TEXT= | + | {{GraueBox|TEXT= |
| + | [[File:P_ID203__Sto_T_2_3_S2_neu.png |frame|Binomial distribution probabilities]] | ||
$\text{Example 2:}$ | $\text{Example 2:}$ | ||
| − | The graph shows the probabilities of the binomial distribution | + | The graph shows the probabilities of the binomial distribution for $I =6$ and $p =0.4$. |
| − | |||
*Thus $M = I+1=7$ probabilities are different from zero. | *Thus $M = I+1=7$ probabilities are different from zero. | ||
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{{GraueBox|TEXT= | {{GraueBox|TEXT= | ||
| − | $\text{Example 3:}$ Another example of the application of the binomial distribution is the ''' | + | $\text{Example 3:}$ Another example of the application of the binomial distribution is the »'''calculation of the block error probability in Digital Signal Transmission'''«. |
If one transmits blocks each of $I =10$ binary symbols over a channel | If one transmits blocks each of $I =10$ binary symbols over a channel | ||
*with probability $p = 0.01$ that one symbol is falsified ⇒ random variable $e_i = 1$, and | *with probability $p = 0.01$ that one symbol is falsified ⇒ random variable $e_i = 1$, and | ||
| + | |||
*correspondingly with probability $1 - p = 0.99$ for an unfalsified symbol ⇒ random variable $e_i = 0$, | *correspondingly with probability $1 - p = 0.99$ for an unfalsified symbol ⇒ random variable $e_i = 0$, | ||
| − | then the new random variable $f$ ⇒ | + | then the new random variable $f$ ⇒ »number of block errors« is: |
:$$f=\sum_{i=1}^{I}e_i.$$ | :$$f=\sum_{i=1}^{I}e_i.$$ | ||
| − | This random variable $f$ can take all integer values between $0$ (no symbol is falsified) and $I$ (all symbols symbol are falsified) . | + | This random variable $f$ can take all integer values between $0$ $($no symbol is falsified$)$ and $I$ $($all symbols symbol are falsified$)$ . |
| − | + | #We denote the probabilities for $\mu$ falsifications by $p_μ$. | |
| − | + | #The case where all $I$ symbols are correctly transmitted occurs with probability $p_0 = 0.99^{10} ≈ 0.9044$ . | |
| − | + | #This also follows from the binomial formula for $μ = 0$ considering the definition $10\, \text{ over }\, 0 = 1$. | |
| − | + | #A single symbol error $(f = 1)$ occurs with the probability $p_1 = \rm 10\cdot 0.01\cdot 0.99^9\approx 0.0914.$ | |
| − | + | #The first factor considers that there are exactly $10\, \text{ over }\, 1 = 10$ possibilities for the position of a single error. | |
| − | + | #The other two factors take into account that one symbol must be falsified and nine must be transmitted correctly if $f =1$ is to hold. | |
| − | + | ||
| − | + | ||
| + | For $f =2$ there are clearly more combinations, namely $10\, \text{ over }\, 2 = 45$, and we get | ||
:$$p_2 = \rm 45\cdot 0.01^2\cdot 0.99^8\approx 0.0041.$$ | :$$p_2 = \rm 45\cdot 0.01^2\cdot 0.99^8\approx 0.0041.$$ | ||
| − | If a block code can correct up to two errors, the block error probability is | + | If a block code can correct up to two errors, the »'''block error probability'''« is |
:$$p_{\rm block} = \it p_{\rm 3} \rm +\hspace{0.1cm}\text{ ...} \hspace{0.1cm} \rm + \it p_{\rm 10}\approx \rm 10^{-4},$$ | :$$p_{\rm block} = \it p_{\rm 3} \rm +\hspace{0.1cm}\text{ ...} \hspace{0.1cm} \rm + \it p_{\rm 10}\approx \rm 10^{-4},$$ | ||
or | or | ||
:$$p_{\rm block} = \rm 1-\it p_{\rm 0}-\it p_{\rm 1}-p_{\rm 2}\approx \rm 10^{-4}.$$ | :$$p_{\rm block} = \rm 1-\it p_{\rm 0}-\it p_{\rm 1}-p_{\rm 2}\approx \rm 10^{-4}.$$ | ||
| − | *One can see that for large | + | *One can see that for large $I$ values the second possibility of calculation via the complement leads faster to the goal. |
| + | |||
*However, one could also consider that for these numerical values $p_{\rm block} ≈ p_3$ holds as an approximation. }} | *However, one could also consider that for these numerical values $p_{\rm block} ≈ p_3$ holds as an approximation. }} | ||
| − | ⇒ Use the interactive HTML5/JS applet [[Applets:Binomial_and_Poisson_Distribution_(Applet)| | + | ⇒ Use the interactive HTML5/JS applet [[Applets:Binomial_and_Poisson_Distribution_(Applet)|»Binomial and Poisson distribution«]] to find the binomial probabilities for any $I$ and $p$ . |
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<br> | <br> | ||
You can calculate the moments in general using the equations in the chapters | You can calculate the moments in general using the equations in the chapters | ||
| − | + | * [[Theory_of_Stochastic_Signals/Moments_of_a_Discrete_Random_Variable|»Moments of a Discrete Random Variable«]], | |
| − | + | ||
| + | * [[Theory_of_Stochastic_Signals/Binomial_Distribution#Probabilities_of_the_binomial_distribution|»Probabilities of the Binomial Distribution»]]. | ||
{{BlaueBox|TEXT= | {{BlaueBox|TEXT= | ||
| − | $\text{Calculation rules:} $ | + | $\text{Calculation rules:} $ For the »'''$k$-th order moment'''« of a binomially distributed random variable, the general rule is: |
| − | |||
| − | For the »'''$k$-th order moment'''« of a binomially distributed random variable, the general rule is: | ||
:$$m_k={\rm E}\big[z^k\big]=\sum_{\mu={\rm 0} }^{I}\mu^k\cdot{I \choose \mu}\cdot p\hspace{0.05cm}^\mu\cdot ({\rm 1}-p)\hspace{0.05cm}^{I-\mu}.$$ | :$$m_k={\rm E}\big[z^k\big]=\sum_{\mu={\rm 0} }^{I}\mu^k\cdot{I \choose \mu}\cdot p\hspace{0.05cm}^\mu\cdot ({\rm 1}-p)\hspace{0.05cm}^{I-\mu}.$$ | ||
From this, we obtain for after some transformations | From this, we obtain for after some transformations | ||
| − | *the first order moment ⇒ | + | *the first order moment ⇒ »linear mean«: |
:$$m_1 ={\rm E}\big[z\big]= I\cdot p,$$ | :$$m_1 ={\rm E}\big[z\big]= I\cdot p,$$ | ||
| − | *the second order moment: | + | *the second order moment ⇒ »power«: |
:$$m_2 ={\rm E}\big[z^2\big]= (I^2-I)\cdot p^2+I\cdot p,$$ | :$$m_2 ={\rm E}\big[z^2\big]= (I^2-I)\cdot p^2+I\cdot p,$$ | ||
| − | *the variance by applying | + | *the variance by applying »Steiner's theorem»: |
:$$\sigma^2 = {m_2-m_1^2} = {I \cdot p\cdot (1-p)} ,$$ | :$$\sigma^2 = {m_2-m_1^2} = {I \cdot p\cdot (1-p)} ,$$ | ||
*the standard deviation: | *the standard deviation: | ||
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| − | The maximum variance $σ^2 = I/4$ is obtained for the | + | The maximum variance $σ^2 = I/4$ is obtained for the »characteristic probability« $p = 1/2$. |
*In this case, the binomial probabilities are symmetric around the mean $m_1 = I/2 \ ⇒ \ p_μ = p_{I–μ}$. | *In this case, the binomial probabilities are symmetric around the mean $m_1 = I/2 \ ⇒ \ p_μ = p_{I–μ}$. | ||
*The more the characteristic probability $p$ deviates from the value $1/2$ , | *The more the characteristic probability $p$ deviates from the value $1/2$ , | ||
| − | # the smaller is the standard deviation $σ$, and | + | # the smaller is the standard deviation $σ$, and |
| − | # the more asymmetric the probabilities | + | # the more asymmetric become the probabilities around the mean $m_1 = I · p$. |
{{GraueBox|TEXT= | {{GraueBox|TEXT= | ||
| − | $\text{Example 4:}$ | + | $\text{Example 4:}$ |
| − | |||
| − | Then holds: | + | As in $\text{Example 3}$, we consider a block of $I =10$ binary symbols, each of which is independently falsified with probability $p = 0.01$ . Then holds: |
*The mean number of block errors is equal to $m_f = {\rm E}\big[ f\big] = I · p = 0.1$. | *The mean number of block errors is equal to $m_f = {\rm E}\big[ f\big] = I · p = 0.1$. | ||
| + | |||
*The standard deviation of the random variable $f$ is $σ_f = \sqrt{0.1 \cdot 0.99}≈ 0.315$. | *The standard deviation of the random variable $f$ is $σ_f = \sqrt{0.1 \cdot 0.99}≈ 0.315$. | ||
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*$m_f = 5$ ⇒ on average, five of the ten bits within a block are wrong, | *$m_f = 5$ ⇒ on average, five of the ten bits within a block are wrong, | ||
| + | |||
* $σ_f = \sqrt{I}/2 ≈1.581$ ⇒ maximum standard deviation.}} | * $σ_f = \sqrt{I}/2 ≈1.581$ ⇒ maximum standard deviation.}} | ||
Latest revision as of 18:32, 7 February 2024
Contents
General description of the binomial distribution
$\text{Definition:}$ The »binomial distribution« represents an important special case for the occurrence probabilities of a discrete random variable.
To derive the binomial distribution, we assume that $I$ binary and statistically independent random variables $b_i$ each can achieve
- the value $1$ with probability ${\rm Pr}(b_i = 1) = p$, and
- the value $0$ with probability ${\rm Pr}(b_i = 0) = 1-p$.
Then the sum $z$ is also a discrete random variable with the symbol set $\{0, \ 1, \ 2,\hspace{0.1cm}\text{ ...} \hspace{0.1cm}, \ I\}$, which is called binomially distributed:
- $$z=\sum_{i=1}^{I}b_i.$$
Thus, the symbol set size is $M = I + 1.$
$\text{Example 1:}$ The binomial distribution finds manifold applications in Communications Engineering as well as in other disciplines:
- It describes the distribution of rejects in statistical quality control.
- It allows the calculation of the residual error probability in blockwise coding.
- The bit error rate of a digital transmission system obtained by simulation is actually a binomially distributed random quantity.
Probabilities of the binomial distribution
$\text{Calculation rule:}$ For the »probabilities of the binomial distribution« with $μ = 0, \hspace{0.1cm}\text{...} \hspace{0.1cm}, \ I$:
- $$p_\mu = {\rm Pr}(z=\mu)={I \choose \mu}\cdot p\hspace{0.05cm}^\mu\cdot ({\rm 1}-p)\hspace{0.05cm}^{I-\mu}.$$
The first term here indicates the number of combinations $($read: $I\ \text{ over }\ μ)$:
- $${I \choose \mu}=\frac{I !}{\mu !\cdot (I-\mu) !}=\frac{ {I\cdot (I- 1) \cdot \ \cdots \ \cdot (I-\mu+ 1)} }{ 1\cdot 2\cdot \ \cdots \ \cdot \mu}.$$
$\text{Additional notes:}$
- For very large values of $I$, the binomial distribution can be approximated by the »Poisson distribution« described in the next section.
- If at the same time the product $I · p \gg 1$, then according to »de Moivre–Laplace's $($central limit$)$ theorem«, the Poisson distribution $($and hence the binomial distribution$)$ transitions to a discrete »Gaussian distribution«.
Binomial distribution probabilities
$\text{Example 2:}$ The graph shows the probabilities of the binomial distribution for $I =6$ and $p =0.4$.
- Thus $M = I+1=7$ probabilities are different from zero.
- In contrast, for $I = 6$ and $p = 0.5$, the probabilities of the binomial distribution are as follows:
- $$\begin{align*}{\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}0) & = {\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}6)\hspace{-0.05cm} =\hspace{-0.05cm} 1/64\hspace{-0.05cm} = \hspace{-0.05cm}0.015625 ,\\ {\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}1) & = {\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}5) \hspace{-0.05cm}= \hspace{-0.05cm}6/64 \hspace{-0.05cm}=\hspace{-0.05cm} 0.09375,\\ {\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}2) & = {\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}4)\hspace{-0.05cm} = \hspace{-0.05cm}15/64 \hspace{-0.05cm}= \hspace{-0.05cm}0.234375 ,\\ {\rm Pr}(z\hspace{-0.05cm} =\hspace{-0.05cm}3) & = 20/64 \hspace{-0.05cm}= \hspace{-0.05cm} 0.3125 .\end{align*}$$
- These are symmetrical with respect to the abscissa value $\mu = I/2 = 3$.
$\text{Example 3:}$ Another example of the application of the binomial distribution is the »calculation of the block error probability in Digital Signal Transmission«.
If one transmits blocks each of $I =10$ binary symbols over a channel
- with probability $p = 0.01$ that one symbol is falsified ⇒ random variable $e_i = 1$, and
- correspondingly with probability $1 - p = 0.99$ for an unfalsified symbol ⇒ random variable $e_i = 0$,
then the new random variable $f$ ⇒ »number of block errors« is:
- $$f=\sum_{i=1}^{I}e_i.$$
This random variable $f$ can take all integer values between $0$ $($no symbol is falsified$)$ and $I$ $($all symbols symbol are falsified$)$ .
- We denote the probabilities for $\mu$ falsifications by $p_μ$.
- The case where all $I$ symbols are correctly transmitted occurs with probability $p_0 = 0.99^{10} ≈ 0.9044$ .
- This also follows from the binomial formula for $μ = 0$ considering the definition $10\, \text{ over }\, 0 = 1$.
- A single symbol error $(f = 1)$ occurs with the probability $p_1 = \rm 10\cdot 0.01\cdot 0.99^9\approx 0.0914.$
- The first factor considers that there are exactly $10\, \text{ over }\, 1 = 10$ possibilities for the position of a single error.
- The other two factors take into account that one symbol must be falsified and nine must be transmitted correctly if $f =1$ is to hold.
For $f =2$ there are clearly more combinations, namely $10\, \text{ over }\, 2 = 45$, and we get
- $$p_2 = \rm 45\cdot 0.01^2\cdot 0.99^8\approx 0.0041.$$
If a block code can correct up to two errors, the »block error probability« is
- $$p_{\rm block} = \it p_{\rm 3} \rm +\hspace{0.1cm}\text{ ...} \hspace{0.1cm} \rm + \it p_{\rm 10}\approx \rm 10^{-4},$$
or
- $$p_{\rm block} = \rm 1-\it p_{\rm 0}-\it p_{\rm 1}-p_{\rm 2}\approx \rm 10^{-4}.$$
- One can see that for large $I$ values the second possibility of calculation via the complement leads faster to the goal.
- However, one could also consider that for these numerical values $p_{\rm block} ≈ p_3$ holds as an approximation.
⇒ Use the interactive HTML5/JS applet »Binomial and Poisson distribution« to find the binomial probabilities for any $I$ and $p$ .
Moments of the binomial distribution
You can calculate the moments in general using the equations in the chapters
$\text{Calculation rules:} $ For the »$k$-th order moment« of a binomially distributed random variable, the general rule is:
- $$m_k={\rm E}\big[z^k\big]=\sum_{\mu={\rm 0} }^{I}\mu^k\cdot{I \choose \mu}\cdot p\hspace{0.05cm}^\mu\cdot ({\rm 1}-p)\hspace{0.05cm}^{I-\mu}.$$
From this, we obtain for after some transformations
- the first order moment ⇒ »linear mean«:
- $$m_1 ={\rm E}\big[z\big]= I\cdot p,$$
- the second order moment ⇒ »power«:
- $$m_2 ={\rm E}\big[z^2\big]= (I^2-I)\cdot p^2+I\cdot p,$$
- the variance by applying »Steiner's theorem»:
- $$\sigma^2 = {m_2-m_1^2} = {I \cdot p\cdot (1-p)} ,$$
- the standard deviation:
- $$\sigma = \sqrt{I \cdot p\cdot (1-p)}.$$
The maximum variance $σ^2 = I/4$ is obtained for the »characteristic probability« $p = 1/2$.
- In this case, the binomial probabilities are symmetric around the mean $m_1 = I/2 \ ⇒ \ p_μ = p_{I–μ}$.
- The more the characteristic probability $p$ deviates from the value $1/2$ ,
- the smaller is the standard deviation $σ$, and
- the more asymmetric become the probabilities around the mean $m_1 = I · p$.
$\text{Example 4:}$
As in $\text{Example 3}$, we consider a block of $I =10$ binary symbols, each of which is independently falsified with probability $p = 0.01$ . Then holds:
- The mean number of block errors is equal to $m_f = {\rm E}\big[ f\big] = I · p = 0.1$.
- The standard deviation of the random variable $f$ is $σ_f = \sqrt{0.1 \cdot 0.99}≈ 0.315$.
In contrast, in the completely falsified channel ⇒ bit error probability $p = 1/2$ results in the values
- $m_f = 5$ ⇒ on average, five of the ten bits within a block are wrong,
- $σ_f = \sqrt{I}/2 ≈1.581$ ⇒ maximum standard deviation.
Exercises for the chapter
Exercise 2.3: Algebraic Sum of Binary Numbers
Exercise 2.4: Number Lottery (6 from 49)
