Let's start the analysis by looking at your "extreme usage" cases. Compare the two cases in detail-low usage period versus high usage period. Discuss differences between the two as well as any surprises. Things you
should cover in your discussion: How much difference was there in average power usage (avg. kW) between the
low-usage and high-usage time periods? What might have been running during the low-usage period that used
energy? Identify likely "stealth" energy users that you could not turn off during the low-usage period. What do
you suppose contributed most to the usage during the high-usage period?

Go to the bathroom and vape

Attach the free body diagram and i will you answer the question.! : d

Answer: a charge of -1.0  × 10⁻⁴ c must be placed  at x = 26 m.the sign of the charge will be the same sign as the  -4.0  µc charge.======electricstatic force between two point charges  is given by    where k is coulomb's constant,  8.99×10⁹  n·m²/c², q₁ and q₂ are the point charges, and r is the distance between the two point charges.assign positive to q₁let q₁ =  6.0 µc, q₂ = -4.0  µc, q₀ represent the charge at the origin, and q₃ represent this new charge to place.the charge at the origin q₀ would experience the following force f₀₁ from q₁, with r = 6.0 m (note that 1  µc = 10⁻⁶ c)    the force from q₂    the force from q₃    the net force on the origin charge, q₀, has to be zero for no electrostatic forcehaving an equation where k and q₀ can be divided out of the equation will allow us to solve for q₃    isolating:     a charge of -1.0  × 10⁻⁴ c must be placed  at x = 26 m.the sign of the charge will be the same as the  -4.0  µc charge