DC Circuits - How to Determine a Bulb's Brightness

AI Thread Summary
When bulb D is unscrewed, the brightness of bulb F increases because it is now in a series circuit with bulb B, allowing the current to pass equally through both. In contrast, when bulb D is in place, the current is divided between the parallel paths, resulting in less current through bulb F and thus lower brightness. The power dissipated by a bulb, which determines its brightness, is influenced by the voltage across it; with D removed, the voltage across F becomes higher. The discussion emphasizes the relationship between current, voltage, and resistance in determining bulb brightness. Understanding these electrical principles clarifies the behavior of the circuit when bulb D is removed.
jkface
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Homework Statement


tPo7e.jpg

The circuit has identical bulbs and an ideal battery. When bulb D is unscrewed from its socket (the socket remains in its place), what would happen to the brightness of bulb F?

Homework Equations


V = IR


The Attempt at a Solution


Since bulb D is unscrewed from it socket and the socket remains in its place, we can replace bulb D with a switch that is open. Assigning resistance of 1 for each bulb, the right side of circuit has 2R and the current for bulb F would be I = V/2R. When the bulb D is back in its place, the resistance of the right side of the circuit would be 5R/3 and the current for bulb F would be I = (3V/5R)/(2/3) = 9V/10R. This shows that when bulb D is unscrewed from its socket, bulb F would have less brightness.

When I entered the above explanation it turned out to be wrong. Can anyone explain why the brightness of the bulb increases?
 
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jkface said:
When the bulb D is back in its place, the resistance of the right side of the circuit would be 5R/3 and the current for bulb F would be I = (3V/5R)/(2/3) = 9V/10R.
Check the current through F. Can it be higher than the main current?

ehild
 
jkface said:

Homework Statement


tPo7e.jpg

The circuit has identical bulbs and an ideal battery. When bulb D is unscrewed from its socket (the socket remains in its place), what would happen to the brightness of bulb F?

Homework Equations


V = IR


The Attempt at a Solution


Since bulb D is unscrewed from it socket and the socket remains in its place, we can replace bulb D with a switch that is open. Assigning resistance of 1 for each bulb, the right side of circuit has 2R and the current for bulb F would be I = V/2R. When the bulb D is back in its place, the resistance of the right side of the circuit would be 5R/3 and the current for bulb F would be I = (3V/5R)/(2/3) = 9V/10R. This shows that when bulb D is unscrewed from its socket, bulb F would have less brightness.

When I entered the above explanation it turned out to be wrong. Can anyone explain why the brightness of the bulb increases?

When globe D is removed, current passes through just B and F on the RHS. As they are in series, the current through each is the same - and the PD across each is thus equal, being half the Emf of the battery. [remember they are equal resistance globes]

When Globe D is/was in position, the current through B is shared through the two parallel arms, so more current flows through B compared to that through F - so the PD across B is greater than that over F, so the PD across B must be more than one half of the Emf of the cell, while the PD across F must be less than a half; so F must be duller when D is there - or if you like brighter when D is removed.
 
ehild said:
Check the current through F. Can it be higher than the main current?

ehild

Now that you mention it, I'm beginning to realize how stupid my answer sounds. If I multiply 3V/5R by 2/3, would that be the right answer?
 
PeterO said:
When globe D is removed, current passes through just B and F on the RHS. As they are in series, the current through each is the same - and the PD across each is thus equal, being half the Emf of the battery. [remember they are equal resistance globes]

When Globe D is/was in position, the current through B is shared through the two parallel arms, so more current flows through B compared to that through F - so the PD across B is greater than that over F, so the PD across B must be more than one half of the Emf of the cell, while the PD across F must be less than a half; so F must be duller when D is there - or if you like brighter when D is removed.

Thank you. I think I'm beginning to understand the problem now. Would I reach the same conclusion if I only discuss voltage differences?
 
jkface said:
Thank you. I think I'm beginning to understand the problem now. Would I reach the same conclusion if I only discuss voltage differences?

The brightness of the globe depends on the power being transformed/dissipated.

Power can be calculated from P = VI or I2R or V2/R

That 3rd form would suggest that Voltage difference would be sufficient.
 
jkface said:
Now that you mention it, I'm beginning to realize how stupid my answer sounds. If I multiply 3V/5R by 2/3, would that be the right answer?

Yes, of course. :smile:

ehild
 
Thanks everyone for helping me!
 

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