Shoukat Ali

Other Schools
Physics Teacher

Biography

I have been teaching Physics to intermediate students.

Education

MS Physics
Other Schools
BS Physics
Other Schools

Educator Statistics

Numerade tutor for 6 years
1890 Students Helped

Topics Covered

Master the Fundamentals of Physics: Learn Physics Basics
Mastering the Rotation of Rigid Bodies: Tips & Techniques
Explore the Fascinating Dynamics of Rotational Motion
Understanding Equilibrium and Elasticity: A Comprehensive Guide
Understanding Moment Impulse and Collisions for Better Physics
Calculating Electrical Power: Resistance and EMF
Master Direct Current Circuits with Our Expert Guide
Electromagnetic Induction: Understanding the Science and Applications
Discover the Science of Sound and Hearing: Your Guide to Better Listening
Explore the Fascinating World of Wave Optics - Unleash Its Potential
Unlocking the Power of Electric Potential: Exploring its Benefits
Understanding Electromagnetic Waves: A Comprehensive Guide
Understanding Reflection and Refraction of Light: A Comprehensive Guide
Understanding Electric Charge and Field: A Comprehensive Guide
Capacitance and Dielectrics: Understanding the Basics
Explore the Fascinating World of Periodic Motion - Learn More Today!
Exploring the Fascinating World of Mechanical Waves
Discover the Power of Gravitation: Exploring the Science Behind It
Understanding the First Law of Thermodynamics: Key Concepts
Understanding the Second Law of Thermodynamics: Key Principles
Understanding Temperature and Heat: A Comprehensive Guide
Unlocking the Secrets of Thermal Properties: Understanding Matter
Understanding Inductance: A Comprehensive Guide
Find Your Dream Job: Discover the Best Work Opportunities
Unlock the Power of Kinetic Energy: Boost Your Efficiency Today
Unlocking the Power of Potential Energy: Discover the Benefits
Save Energy and Money with Effective Conservation Techniques
Motion in 2d or 3d
Mastering Motion: Achieving Efficiency Along a Straight Line
Mastering Newton's Laws: Tips for Applying Them Effectively
Exploring the Fascinating World of Quantum Physics
Discovering the Fundamentals: Newton's Laws of Motion Explained
Unlock the Secrets of Fluid Mechanics with Our Expert Guide
Exploring the Wonders of Atomic Physics: A Comprehensive Guide
Understanding Alternating Current: A Comprehensive Guide
Understanding Gauss's Law: A Comprehensive Guide
Unlocking the Power of Magnetic Fields and Forces
Discovering the Sources of Magnetic Fields: A Comprehensive Guide
Discover the Fascinating World of Nuclear Physics
Breaking Limits: Unlock Your Potential with Our Expert Solutions
Exploring the World of Derivatives: A Comprehensive Guide
Explore the Power of Continuous Functions: Boost Your Mathematical Skills
Mastering Integrals: Tips and Tricks for Calculus Success
Integration
Mastering Integration Techniques for Optimal Results
Differential Equations Made Simple: Expert Tips & Resources
Mastering Partial Derivatives: Essential Techniques and Tips
Fluid Mechanics
Discover the Fascinating World of Particle Physics Today
Rotational Motion
Oscillatory Motion
Temperature and the Kinetic Theory of Gases
Kinetic Theory Of Gases

Shoukat's Textbook Answer Videos

03:46
University Physics with Modern Physics

Consider the circuit of Fig. E25.30. (a) What is the total rate at which electrical energy is dissipated in the 5.0-$\Omega$ and 9.0-$\Omega$ resistors? (b) What is the power output of the 16.0-V battery? (c) At what rate is electrical energy being converted to other forms in the 8.0-V battery? (d) Show that the power output of the 16.0-V battery equals the overall rate of consumption of electrical energy in the rest of the circuit.

Chapter 25: Current, Resistance, and Electromotive Force
Section 5: Energy and Power in Electric Circuits
Shoukat Ali
06:05
University Physics with Modern Physics

An underwater camera has a lens with focal length in air of 35.0 mm and a maximum aperture of $f/$2.80. The film it uses has an emulsion that is sensitive to light of frequency 6.00 $\times$ 10$^{14}$ Hz. If the photographer takes a picture of an object 2.75 m in front of the camera with the lens wide open, what is the width of the smallest resolvable detail on the subject if the object is (a) a fish underwater with the camera in the water and (b) a person on the beach with the camera out of the water?

Chapter 36: Diffraction
Shoukat Ali
03:05
University Physics with Modern Physics

It has been proposed to use an array of infrared telescopes spread over thousands of kilometers of space to observe planets orbiting other stars. Consider such an array that has an effective diameter of 6000 km and observes infrared radiation at a wavelength of 10 $\mu$m. If it is used to observe a planet orbiting the star 70 Virginis, which is 59 light-years from our solar system, what is the size of the smallest details that the array might resolve on the planet? How does this compare to the diameter of the planet, which is assumed to be similar to that of Jupiter (1.40 $\times$ 10$^{5}$ km)? (Although the planet of 70 Virginis is thought to be at least 6.6 times more massive than Jupiter, its radius is probably not too different from that of Jupiter. Such large planets are thought to be composed primarily of gases, not rocky material, and hence can be greatly compressed by the mutual gravitational attraction of different parts of the planet.)

Chapter 36: Diffraction
Shoukat Ali
03:35
University Physics with Modern Physics

$Quasars, an abbreviation for quasi-stellar radio sources$, are distant objects that look like stars through a telescope but that emit far more electromagnetic radiation than an entire normal
galaxy of stars. An example is the bright object below and to the left of center in Fig. P36.60; the other elongated objects in this image are normal galaxies. The leading model for the structure
of a quasar is a galaxy with a supermassive black hole at its center. In this model, the radiation is emitted by interstellar gas and dust within the galaxy as this material falls toward the black hole. The radiation is thought to emanate from a region just a few light-years in diameter. (The diffuse glow surrounding the bright quasar shown in $\textbf{Fig. P36.60}$ is thought to be this quasar's host galaxy.) To investigate this model of quasars and to study other exotic astronomical
objects, the Russian Space Agency plans to place a radio telescope in an orbit that extends to 77,000 km from the earth. When the signals from this telescope are combined with signals
from the ground-based telescopes of the VLBA, the resolution will be that of a single radio telescope 77,000 km in diameter. What is the size of the smallest detail that this arrangement could resolve in quasar 3C 405, which is 7.2 $\times$ 10$^{8}$ light-years from earth, using radio waves at a frequency of 1665 MHz? (Hint: Use Rayleigh's criterion.) Give your answer in light-years and in kilometers.

Chapter 36: Diffraction
Shoukat Ali
01:51
University Physics with Modern Physics

How fast must a rocket travel relative to the earth so that time in the rocket "slows down" to half its rate as measured by earthbased observers? Do present-day jet planes approach such speeds?

Chapter 37: Relativity
Section 3: Relativity of Time Intervals
Shoukat Ali
03:15
University Physics with Modern Physics

An observer in frame $S'$ is moving to the right (+$x$-direction) at speed $u$ = 0.600c away from a stationary observer in frame S. The observer in $S'$ measures the speed $v'$ of a particle moving to the right away from her. What speed $v'$ does the observer in S measure for the particle if (a) $v'$ = 0.400c; (b) $v'$ = 0.900c; (c) $v'$ = 0.990c?

Chapter 37: Relativity
Section 5: The Lorentz Transformations
Shoukat Ali
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