What is the main function of an ignition safety switch?
Answer:
to produce spark in engen
Explanation:
The main function of an ignition safety switch in an automobile is to prevent the engine from starting without the key being inserted into the ignition.
Explanation:The main function of an ignition safety switch in an automobile is to prevent the engine from starting without the key being inserted into the ignition. It acts as a security measure to prevent unauthorized individuals from starting the vehicle. The switch is typically located close to the steering column and is connected to the ignition system.
When the key is inserted and turned in the ignition, it completes the circuit and allows electrical current to flow to the ignition system, which then starts the engine. If the ignition safety switch is not engaged or faulty, the circuit remains incomplete, and the engine will not start even if the key is turned.
To test the resilience of its bumper during low-speed collisions, a 4 060-kg automobile is driven into a brick wall. the car's bumper behaves like a spring with a force constant 8.00 106 n/m and compresses 3.72 cm as the car is brought to rest. what was the speed of the car before impact, assuming no mechanical energy is transformed or transferred away during impact with the wall
In egypt, the physiologic density is ______ greater than the arithmetic density [estimate value], because _______ [reason for difference].
A projectile is launched with an initial velocity of 25m/s at 35 degrees above the horizontal. assuming that the projectile returns to the same height, what is the final velocity of this projectile
The final velocity of a projectile launched at an angle above the horizontal and returning to the same height is equal to its initial velocity in the opposite direction.
Explanation:When a projectile is launched at an angle above the horizontal and returns to the same height, its final velocity will have the same magnitude as its initial velocity but in the opposite direction. This is because the horizontal component of velocity remains constant while the vertical component changes due to the force of gravity. In this case, the initial velocity is 25 m/s and the angle is 35 degrees above the horizontal, so the final velocity will also be 25 m/s but in the opposite direction.
Name of the thing that hangs off a zipper
Average velocity is different than average speed because calculating average velocity involves
Answer:
Displacement
Explanation:
We are given that average velocity is different than average speed.
We have to find what involves average velocity.
Average velocity:It is defined as the displacement per unit time.
Mathematical representation,
Average velocity=[tex]\frac{displacement}{time}=\frac{ds}{dt}[/tex]
Average speed:It is defined as the distance per unit time.
Average speed=[tex]\frac{distance}{time}=[tex]\frac{s}{t}[/tex]
Average velocity is different from average speed because calculating average velocity involves displacement but average speed involves distance.
People who view society as a set of interrelated parts that work together to produce a stable social system are said to employ the
a.
manifest function.
c.
interactionist perspective.
b.
theoretical perspective.
d.
functionalist perspective.
The people who see society as a collection of interconnected components that cooperate to create a stable social order are said to use a Functionalist Perspective. Hence, option D is correct.
What is a Functionalist Perspective?Each component of society is interrelated and contributes to the stability and smooth operation of society as a whole, according to the functionalist perspective in sociology. For instance, the government pays for the education of the family's children, who then pay taxes that the state needs to function.
In other words, the family depends on the school to assist kids in getting decent careers as adults, so they can support and raise their own families.
If everything works out, society's constituent elements provide production, stability, and order. If things do not go as planned, the components of society must then adjust to reestablish a new order, stability, and productivity.
Hence, the people who see society as a collection of interconnected components that cooperate to create a stable social order are said to use a Functionalist Perspective.
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On a cloudless day, what happens to most of the visible light headed toward earth? hints on a cloudless day, what happens to most of the visible light headed toward earth? it is reflected by earthâs atmosphere. it is absorbed and reemitted by gases in earthâs atmosphere. it is completely reflected by earthâs surface. it reaches earthâs surface, where some is reflected and some is absorbed.
A missile is fired from a jet flying horizontally at mach 1 (1100 ft/s). The missile has a horizontal acceleration of 1000ft/s. Calculate its horizontal velocity at 10.0 seconds after it is fired
To find the horizontal velocity of the missile at 10.0 seconds after firing, use the motion equation v = u + at, with u = 1100 ft/s and a = 1000 ft/s²2. This results in a final velocity (v) of 11100 ft/s.
Calculating the Horizontal Velocity of a Missile
To calculate the horizontal velocity of the missile at 10.0 seconds after it is fired, we can use the equation of motion which relates initial velocity, acceleration, and time to find the final velocity. The equation we will use is:
v = u + at
Where:
v is the final velocity
u is the initial velocity
a is the acceleration
t is the time
Given:
Initial velocity (u) = Mach 1 = 1100 ft/s
Horizontal acceleration (a) = 1000 ft/s²
Time (t) = 10.0 s
To find the final velocity (v):
v = 1100 ft/s + (1000 ft/s² * 10.0 s)
v = 1100 ft/s + 10000 ft/s
v = 11100 ft/s
Therefore, the horizontal velocity of the missile at 10.0 seconds after being fired is 11100 ft/s.
As much as 90% of the matter in the universe may be unseen “dark matter.” where is this dark matter?
Final answer:
Dark matter is an unseen substance that makes up about 90% of the universe's mass, detectable through its gravitational effects on visible matter. It exists in a halo around galaxies and is essential for understanding the universe's composition and expansion fate.
Explanation:
The unseen matter that may constitute as much as 90% of the universe is known as dark matter. This dark matter is not directly observable because it does not emit or reflect any electromagnetic radiation. However, its existence is inferred from gravitational effects on visible matter, radiation, and the large-scale structure of the universe.
For example, galaxies contain far more mass than can be accounted for by the visible objects we can observe, and this extra mass is attributed to dark matter. The rapid rotation of stars on the outskirts of galaxies is one such gravitational effect indicating the presence of dark matter in a halo around the galaxies.
Discovering the true nature of dark matter is crucial as it may provide insights into particle physics and cosmology. There are theories that dark matter could be composed of neutrinos with a small mass or entirely new types of particles that have never been detected.
The understanding and evidence of dark matter continue to evolve, highlighting its importance in the universe's critical density and its possible role in the ultimate fate of the cosmic expansion.
Which example identifies a change in motion that produces acceleration?
a. a ball moving at a constant speed around a circular track
b. a particle moving in a vacuum at constant velocity
c. a speed skater moving at a constant speed on a straight track
d. a vehicle moving down the street at a steady speed?
Option (a) is correct. The motion of a ball moving in a circular path at a constant speed is termed as the motion with acceleration.
Explanation:
The acceleration of a body is defined as the rate of change of velocity of the body. If the velocity of object under motion continues to change during the motion, the object is considered to be moving under acceleration.
The change in velocity is not only about the change in the magnitude of the speed of the object but it is also the change in the direction of motion of the object moving at a constant speed.
The motion of a particle in a circular path at a steady speed is an accelerated motion because the direction of motion of the ball changes at every instant during its motion in a circular path. The change in direction also changes the velocity of the object and therefore, it is categorized as the accelerated motion.
The motion of a particle at constant velocity in vacuum, a skater moving with a constant speed on a straight track and a vehicle moving on a street at steady speed are not considered as the accelerated motion because the velocity of the body does not change and the direction of motion also remains the same during the motion.
Thus, Option (a) is correct. The motion of a ball moving in a circular path at a constant speed is termed as the motion with acceleration.
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Answer Details:
Grade: High School
Subject: Physics
Chapter: Motion in one dimension
Keywords:
Acceleration, velocity, rate of change, speed, direction of motion, steady speed, straight track, circular track, constant, vacuum.
How much force is needed to accelerate an object of mass 90 kg at a rate of 1.2 m/s2? 0.013 N 75 N 108 N 1080 N
Force needed to accelerate an object is 108 N. The correct option is third.
What is Net force?When two or more forces are acting on the system of objects, then the to attain equilibrium, net force must be zero.
From the Newton's second law of motion, force is given by
F = ma
where, m is the mass of the object and a is the acceleration
Given
Plug the values, we get
F = 90 x1.2
F = 108 N
So, the force needed is 108 N.
Thus, the correct option is third.
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Which two vectors, when subtracted (i.e., when one vector is subtracted from the other), will have the largest magnitude?
Given: Please see the attached image below.
To be able to subtract vectors, we can either use the parallelogram method or the triangle method. Take note that the only difference is that alternatively adding vectors A and B, we will instead be adding A and – B. When we ponder of vector subtraction, we must anticipate about it in terms of adding a negative vector. A negative vector has the same magnitude as the original vector, however, it has an opposite direction.
So in this problem, the two vectors that will have the largest magnitude are A & F when subtracted (i.e., when one vector is subtracted from the other).
The two vectors that when subtracted will have the largest magnitude are the two vectors among the options that individually have the largest magnitude.
Vectors have magnitude and direction. As such, we also consider the direction of vector quantities when operating on them. The magnitudes of the vectors were not specified in the question.
However, the two vectors that when subtracted will have the largest magnitude are the two vectors among the options that individually have the largest magnitude.
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Two identical loudspeakers, speaker 1 and speaker 2, are 2.0 m apart and are emitting 1700-hz sound waves into a room where the speed of sound is 340 m/s. consider a point 4.0 m in front of speaker 1, which lies along a line from speaker 1, that is perpendicular to a line between the two speakers. is this a point of maximum constructive interference, a point of perfect destructive interference, or something in between?
Final answer:
The point in question is not a location of perfect constructive or destructive interference; it is a location of nearly constructive interference due to the path length difference being not an integer or half-integer multiple of the wavelength. Additionally, the minimum distance between two speakers for sounds to arrive at noticeably different times is 0.34 meters.
Explanation:
To determine the type of interference at the given point, we need to calculate the path length difference between the sound waves emanating from both speakers to that point. The frequency of the sound waves is 1700 Hz, and the speed of sound in the room is 340 m/s. The wavelength (λ) can be found using the relationship λ = v/f, where v is the speed of sound and f is the frequency of the sound wave. Substituting the given values, we get λ = 340 m/s / 1700 Hz = 0.2 m.
Now, since the point is 4.0 m in front of speaker 1, and the two speakers are 2.0 m apart, the path length from speaker 2 to the point is the hypotenuse of a right-angled triangle with sides of 4.0 m and 2.0 m. Hence, the path length from speaker 2 is given by √(4.0² + 2.0²) = √(16 + 4) = √20 ≈ 4.47 m. The path length difference between the waves from speaker 2 and speaker 1 is therefore 4.47 m - 4.0 m = 0.47 m.
To find out whether this is a point of constructive interference, destructive interference, or something in between, we compare the path length difference to the wavelength. In this case, the path length difference is 0.47 m, which is not a multiple of the wavelength (0.2 m) or half-wavelength. It's something in between; specifically, it is 2.35 wavelengths (0.47 m / 0.2 m = 2.35). Because this is not equal to an integer or a half-integer multiple of the wavelength, the point will be a location of partial constructive or destructive interference depending on the actual fractional part of the wavelength multiple. In this case, 0.35 wavelengths correspond to a phase difference of 0.35 * 360 degrees, which indicates the interference will be nearly constructive but not perfectly.
The minimum distance between two speakers for sounds to arrive at noticeably different times would be the product of the speed of sound and the time difference capability of the human ear. The speed of sound is given at 340 m/s, and the human ear can differentiate sounds 1.00 ms apart. Thus, distance = speed x time = 340 m/s x 1.00 ms = 340 m/s x 1.00 x 10-3 s = 0.34 m.
Lines with irregular meter and length are called _____.
Lines with irregular meter and length are called Free Verse.
Free Verse, a literary device in literature refers to the poetry which is free from defects of regular rhythm or meter and length. There is no rhythm of the words, and no rhyme scheme in such kind of literary pieces. These kind of poems simply do not follow the rules of poetry.
Floods, droughts, fires, and earthquakes are examples of _____.
Natural disasters
Explanation;Floods, droughts, fires, and earthquakes are examples of natural disasters.Natural disasters are events that occur as a result of natural processes of the earth and cause adverse effects. They include, floods, volcanic eruptions, tsunamis, tornadoes, and hurricanes among others.These events are extreme, sudden events caused by environmental factors that injure people and damage property. For example, floods and earthquakes may strike anywhere on earth , often without warning.Salt water is denser than fresh water. a ship floats in both fresh water and salt water. compared to the fresh water, the volume of water displaced in the salt water is
Final answer:
Compared to fresh water, a ship displaces less volume of salt water because salt water is denser, which means the ship will float higher in salt water.
Explanation:
When a ship floats in both fresh water and salt water, the volume of water displaced in the salt water is less compared to fresh water. This is because salt water is denser than fresh water. According to Archimedes' Principle, an object submerged in a fluid will displace a volume of fluid equal to its own weight. Since salt water is denser, a ship doesn't need to displace as much volume of water in saltwater to equal its weight and achieve buoyancy. This is the main reason why a ship will float higher in salt water than in fresh water.
Which is an example of natural erosion? ice forming in cracks of rocks acid rain falling on sidewalks waves washing over rocks on the beach water washing away soil in an area with off-road vehicles
Answer: waves washing over rocks on the beach
Explanation:
A natural erosion is a phenomena of removal of the top layer of the soil or any other surface material by the action of the natural physical agents like water, wind and others. Waves washing over rocks on the beach is the correct example of natural erosion because waves from any water body are naturally generated by the effect of wind and gravity these can wipe the surface materials present over the rocks on the beach.
Which refers to the temperature to which air would have to be cooled to reach saturation?
Answer: It is called Dew Point
Explanation: The dew point is the exact temperature to which air must be cooled to become saturated with water vapor, if further cooled, the water vapor will condense to form liquid water.
An astronaut is taking a space walk near the shuttle when her safety tether breaks. what should the astronaut do to get back to the shuttle
An untethered astronaut can return to the shuttle by using conservation of momentum or a safety jetpack known as Simplified Aid for EVA Rescue (SAFER). The first method involves throwing an object in the opposite direction, and the other involves using SAFER to propel back.
Explanation:If an astronaut finds themselves adrift in space without a tether, their best bet would be to try and use conservation of momentum to return to the shuttle. They can do this by throwing an object in the opposite direction they wish to travel -- such as a tool or even their own glove. This action would propel them back towards the shuttle due to Isaac Newton's Third Law of Motion: For every action, there is an equal and opposite reaction.
Additionally, astronauts carry a safety jetpack called a Simplified Aid for EVA Rescue (SAFER) during spacewalks. They could use this to propel themselves back towards the shuttle.
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What one initial difference is ultimately responsible for the vastly different conditions on venus compared to earth?
Final answer:
The vastly different conditions on Venus compared to Earth are primarily due to Venus experiencing a runaway greenhouse effect, which led to high temperatures and surface pressures, and the permanent loss of water. Earth managed to maintain liquid water and moderate conditions, unlike the dry and inhospitable Venus.
Explanation:
Initial Difference Leading to Varying Planetary Conditions
The one initial difference that is ultimately responsible for the vastly different conditions on Venus compared to Earth is the presence and fate of water which led to a runaway greenhouse effect on Venus. Unlike Earth, which managed to maintain a delicate balance allowing liquid water to persist, Venus experienced a runaway greenhouse effect due to intense surface heating and a lack of water recycling back into the atmosphere. This resulted in temperatures on Venus reaching around 730 K (over 850 °F), high surface pressure 90 times that of Earth, and a dense and dry atmosphere that diverged greatly from Earth's moderate condition that supports life.
While Venus started with comparable conditions to Earth and Mars, its proximity to the Sun and the subsequent runaway greenhouse effect caused permanent water loss, which contrasted sharply with Earth's retention of water and Mars's freezing over due to lost atmospheric CO₂. Venus's atmosphere became massive and dry, with a CO₂-dominated environment that traps heat and prevents the establishment of the conditions necessary for life as we know it.
A 200 g oscillator in a vacuum chamber has a frequency of 2.0 hz. when air is admitted, the oscillation decreases to 60% of its initial amplitude in 50 s. how many oscillations will have been completed when the amplitude is 30% of its initial value?
Approximately 235 oscillations will have been completed when the amplitude of the oscillator decreases to 30% of its initial value.
To solve this problem, let's first understand the concept. The amplitude of an oscillator in simple harmonic motion decreases over time when air is admitted due to damping. We'll use the concept of exponential decay to model the decrease in amplitude.
The formula for exponential decay is:
[tex]\[ A(t) = A_0 \times e^{-\frac{t}{\tau}} \][/tex]
Where:
- A(t) is the amplitude at time t.
- [tex]\( A_0 \)[/tex] is the initial amplitude.
- [tex]\( \tau \)[/tex] is the time constant, which depends on the damping coefficient.
- e is the base of the natural logarithm.
Given that the amplitude decreases to 60% of its initial value in 50 seconds, we can use this information to find the time constant [tex]\( \tau \).[/tex]
[tex]\[ 0.6A_0 = A_0 \times e^{-\frac{50}{\tau}} \][/tex]
Solving for [tex]\( \tau \):[/tex]
[tex]\[ e^{-\frac{50}{\tau}} = 0.6 \][/tex]
[tex]\[ -\frac{50}{\tau} = \ln(0.6) \][/tex]
[tex]\[ \tau = -\frac{50}{\ln(0.6)} \][/tex]
Now, we can use the value of [tex]\( \tau \)[/tex] to find the time it takes for the amplitude to decrease to 30% of its initial value.
[tex]\[ 0.3A_0 = A_0 \times e^{-\frac{t}{\tau}} \][/tex]
Solving for t:
[tex]\[ e^{-\frac{t}{\tau}} = 0.3 \][/tex]
[tex]\[ -\frac{t}{\tau} = \ln(0.3) \][/tex]
[tex]\[ t = -\tau \times \ln(0.3) \][/tex]
Now, we need to find the number of oscillations completed during this time. We know that the frequency of oscillation is 2.0 Hz, which means the oscillator completes 2 oscillations every second.
Number of oscillations = frequency × time
Number of oscillations = 2.0 × t
Let's compute these values.
First, let's calculate the value of [tex]\( \tau \):[/tex]
[tex]\[ \tau = -\frac{50}{\ln(0.6)} \][/tex]
[tex]\[ \tau \approx -\frac{50}{-0.5108} \][/tex]
[tex]\[ \tau \approx 97.85 \, \text{s} \][/tex]
Now, let's find the time it takes for the amplitude to decrease to 30% of its initial value:
[tex]\[ t = -\tau \times \ln(0.3) \][/tex]
[tex]\[ t \approx -97.85 \times \ln(0.3) \][/tex]
[tex]\[ t \approx 97.85 \times 1.2039 \][/tex]
[tex]\[ t \approx 117.65 \, \text{s} \][/tex]
Now, let's find the number of oscillations completed during this time:
Number of oscillations [tex]= 2.0 \times t[/tex]
Number of oscillations [tex]\approx 2.0 \times 117.65[/tex]
Number of oscillations [tex]\approx 235.3[/tex]
Since the number of oscillations must be a whole number, we can assume it to be 235 oscillations.
Therefore, when the amplitude is 30% of its initial value, approximately 235 oscillations will have been completed.
Which of the following describes the mechanical advantage of a compound machine?
The pulse site located at the point where the upper leg bends is called the
The climate zones lying between 23.5 and 66.5 north and south latitude are called the
Answer:
A
Explanation:
Consider the transition from the energy levels n = 3 to n = 6. what is the wavelength associated with this transition, in nm?
What best describes the overall impact of wilhelm roentgen's discovery of x-rays?
What is the most relevant characteristic of motion
Liquid flows through a 4.0 cm diameter pipe at 1.0 m/s. there is a 2.0 cm diameter restriction on the line. what is the velocity in this restriction?
The question pertains to the principle of continuity in fluid dynamics. When fluid flows from a wider to a narrower part of a pipe, its velocity increases to ensure that the mass flow rate remains constant. The velocity at the restriction can be found by plugging the appropriate area and velocity values from the wider part of the pipe into the continuity equation.
Explanation:The subject in question relates to the physics principle of fluid dynamics. Specifically, we're discussing the continuity equation, which states that the mass flow rate must be constant throughout the pipe, irrespective of changes in the pipe's diameter. This is because the fluid is incompressible, meaning the same amount of fluid must flow past any point in the tube in a given time to ensure continuity of flow. Consequently, when the cross-sectional area of the pipe decreases, the velocity increases.
The formula that represents the continuity equation is A₁V₁= A₂V₂, where A represents the cross-sectional area of the pipe and V represents the velocity of the fluid. To find the velocity at the restriction (V₂), we must plug in the values for A₁, V₁, and A₂. Here, A₁ is the cross-sectional area of the larger part of the pipe, V₁ is the velocity in the larger pipe, and A₂ is the cross-sectional area of the restricted part.
To calculate A₁ and A₂, we use the formula for the area of a circle, which is A=πr². For A₁, r (radius) is half of the larger diameter, that is, 2 cm and for A₂, r is 1 cm (half of the restricted diameter). Substituting these values into the continuity equation will yield the desired velocity at the restriction (V₂).
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John rows his canoe due east across a river at 5.5 miles per hour. if the river is flowing south at 4 miles per hour, find john’s direction.