Examples of sigma in the following topics:
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- Sigma factors are proteins that function in transcription initiation .
- The activity of sigma factors within a cell is controlled in numerous ways.
- However, if transcription of genes is not required, sigma factors will not be active.
- The anti-sigma factors will bind to the RNA polymerase and prevent its binding to sigma factors present at the promoter site.
- The anti-sigma factors are responsible for regulating inhibition of transcriptional activity in organisms that require sigma factor for proper transcription initiation.
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- Sigma factor expression is often associated with environmental changes that cause changes in gene expression .
- Sigma factors include numerous types of factors.
- The most commonly studied sigma factors are often referred to as a RpoS proteins as the rpoS genes encode for sigma proteins of various sizes.
- Specifically, the translational control of the sigma factor is a major level of control.
- The translational control of sigma factors involves the presence and function of small noncoding RNAs.
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- $\displaystyle I_\nu (z,\mu ) = S_\nu - \frac{\mu}{\alpha_\nu +\sigma_\nu} \frac{\partial I_\nu}{\partial z}.$
- $\displaystyle F_\nu(z) = \int I_\nu^{(1)} \cos\theta d \Omega = -2\pi \frac{\partial B_\nu}{\partial z} \frac{1}{\alpha_\nu +\sigma_\nu} \int_{-1}^{+1} \mu^2 d \mu \\ \displaystyle = -\frac{4\pi}{3} \frac{1}{\alpha_\nu +\sigma_\nu} \frac{\partial B_\nu}{\partial z} = -\frac{4\pi}{3} \frac{1}{\alpha_\nu +\sigma_\nu} \frac{\partial B_\nu}{\partial T} \frac{\partial T}{\partial z}$
- $\displaystyle \frac{1}{\alpha_R} \equiv \frac{\int_0^\infty \left (\alpha_\nu +\sigma_\nu\right)^{-1} \frac{\partial B_\nu}{\partial T} d\nu}{\int_0^\infty \frac{\partial B_\nu}{\partial T} d\nu} = \frac{\pi}{4\sigma T^3} \int_0^\infty \left (\alpha_\nu +\sigma_\nu\right)^{-1} \frac{\partial B_\nu}{\partial T} d\nu$
- where $\alpha_R$ is the Rosseland mean absorption coefficient.In stellar astrophysics one often uses the column density $\Sigma$ as the independent variable rather than $z$, $d\Sigma = \rho dz$.Making the substitution yields
- $\displaystyle F(z) = -\frac{16 \sigma T^3}{3\alpha_R} \rho \frac{\partial T}{\partial \Sigma}.= -\frac{16 \sigma T^3}{3\kappa_R} \frac{\partial T}{\partial \Sigma}
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- This probability distribution has the mean and variance, denoted by $\mu$ and $\sigma ^2$, respectively.
- As shown below, the probability to have $x$ in the range $[\mu - \sigma, \mu + \sigma]$ can be calculated from the integral
- Probability distribution function of a normal (or Gaussian) distribution, where mean $\mu=0 $ and variance $\sigma^2=1$.
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- If X and Y are two random variables with variances $\sigma^2_{x_1}$ and $\sigma^2_y$, then the variance of X−Y is $\sigma^2_x+\sigma^2_y$.
- Likewise, the variance corresponding to $\bar{x}_1-\bar{x}_2$ is $\sigma^2_{x_1}+\sigma^2_{x_2}$.
- Because $\sigma^2_{x_1}$ and $\sigma^2_{x_2}$are just another way of writing $SE^2_{x_1}$and $SE^2_{x_2}$, the variance associated with $\bar{x_1}-\bar{x_2}$ may be written as $SE^2_{x_1}+SE^2_{x_2}$.
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- Six Sigma and Lean are two popular operations-management theories that help managers improve the efficiency of their production processes.
- In order to accomplish this task, managers utilize various tools, two of the most influential being Six Sigma and Lean.
- Six Sigma is a strategy designed to improve the quality of process outputs.
- In many ways, Lean manufacturing and Six Sigma is reminiscent of Henry Ford and systematic process improvements.
- Lean and Six Sigma are the two main tools for managers in operations management.
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- Sigma notation, denoted by the uppercase Greek letter sigma $\left ( \Sigma \right ),$ is used to represent summations—a series of numbers to be added together.
- One way to compactly represent a series is with sigma notation, or summation notation, which looks like this:
- The main symbol seen is the uppercase Greek letter sigma.
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- Single covalent bonds are sigma bonds, which occur when one pair of electrons is shared between atoms.
- The strongest type of covalent bonds are sigma bonds, which are formed by the direct overlap of orbitals from each of the two bonded atoms.
- Regardless of the atomic orbital type, sigma bonds can occur as long as the orbitals directly overlap between the nuclei of the atoms.
- These are all possible overlaps between different types of atomic orbitals that result in the formation of a sigma bond between two atoms.
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- $\omega \ll\ \omega_0: \sigma(\omega) \rightarrow \sigma_T \left (\frac{\omega}{\omega_0} \right )^4 $