In the given circuit, the current flowing through the resistance 20\ Omega$20\ \Omega$ is 0.3text A$0.3\text{ A}$, while the ammeter reads 0.9text A$0.9\text{ A}$. The value of R_1$R_1$ is ________ Omega$\Omega$.
The diagram displays a circuit consisting of three parallel branches containing R1, a 20 Ohm resistor, and a 15 Ohm resistor, with an ammeter in series.
Numerical Answer Type:
Enter a numerical valueAnswer: 30 to 30+4 marks
Solution & Explanation
### Related Formula
For parallel branches, the potential difference V$V$ across each branch is identical:
V = I_i R_i$V = I_i R_i$
According to Kirchhoff's Current Law, the total current I_texttotal$I_{\text{total}}$ is the sum of currents in all parallel branches:
I_texttotal = i_1 + i_2 + i_3$I_{\text{total}} = i_1 + i_2 + i_3$
### Core Logic
Analyzing the circuit diagram:
* Branch 1: Current i_1$i_1$ through 20\ Omega$20\ \Omega$ is 0.3text A$0.3\text{ A}$.
* Branch 2: Contains 15\ Omega$15\ \Omega$ resistor with current i_2$i_2$.
* Branch 3: Contains resistor R_1$R_1$ with current i_3$i_3$.
Since the branches are in parallel, they have the same potential difference V_AB$V_{AB}$:
V_AB = i_1 times 20\ Omega = 0.3text A times 20\ Omega = 6text V$V_{AB} = i_1 \times 20\ \Omega = 0.3\text{ A} \times 20\ \Omega = 6\text{ V}$
### Step 1: Calculate Currents
Current through the second branch (15\ Omega$15\ \Omega$ resistor) is:
i_2 = fracV_AB15\ Omega = frac6text V15\ Omega = 0.4text A$i_2 = \frac{V_{AB}}{15\ \Omega} = \frac{6\text{ V}}{15\ \Omega} = 0.4\text{ A}$
Total current read by the ammeter is 0.9text A$0.9\text{ A}$. Thus:
i_1 + i_2 + i_3 = 0.9text A$i_1 + i_2 + i_3 = 0.9\text{ A}$0.3text A + 0.4text A + i_3 = 0.9text A$0.3\text{ A} + 0.4\text{ A} + i_3 = 0.9\text{ A}$0.7text A + i_3 = 0.9text A implies i_3 = 0.2text A$0.7\text{ A} + i_3 = 0.9\text{ A} \implies i_3 = 0.2\text{ A}$
### Step 2: Calculate R1
Now use the voltage relation for the branch containing R_1$R_1$:
i_3 times R_1 = V_AB$i_3 \times R_1 = V_{AB}$(0.2text A) times R_1 = 6text V$(0.2\text{ A}) \times R_1 = 6\text{ V}$R_1 = frac60.2 = 30\ Omega$R_1 = \frac{6}{0.2} = 30\ \Omega$The diagram displays a circuit consisting of three parallel branches containing R1, a 20 Ohm resistor, and a 15 Ohm resistor, with an ammeter in series.
### Pattern Recognition
In parallel networks, finding the branch voltage is always the primary step. Once V = 6text V$V = 6\text{ V}$ is established, the remaining branch currents are easily found using Ohm's Law and current conservation.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Physics: Current Electricity
Keywords:#current flowing through the resistance 20 ohm#JEE Main 2024 Evening Q58#Current Electricity JEE Main 2024#Kirchhoff's Laws JEE Main 2024#Ammeter#Parallel Branches#Kirchhoff's Current Law
More Current Electricity Previous-Year Questions — Page 5
Q32jee_main_2024_29_jan_morningElectric Current and Charge
The electric current through a wire varies with time as I = I_0 + beta t$I = I_0 + \beta t$, where I_0 = 20 mathrm~A$I_0 = 20 \mathrm{~A}$ and beta = 3 mathrm~A / s$\beta = 3 \mathrm{~A / s}$. The amount of electric charge crossed through a section of the wire in 20 mathrm~s$20 \mathrm{~s}$ is:
A.80 mathrm~C$80 \mathrm{~C}$
B.1000 mathrm~C$1000 \mathrm{~C}$
C.800 mathrm~C$800 \mathrm{~C}$
D.1600 mathrm~C$1600 \mathrm{~C}$
Solution
### Related Formula
The relationship between current, charge, and time is given by:
I = fracdqdt implies q = int I \, dt$I = \frac{dq}{dt} \implies q = \int I \, dt$
### Core Logic
Given the current variation:
I = I_0 + beta t$I = I_0 + \beta t$
Substituting the given values, I_0 = 20 mathrm~A$I_0 = 20 \mathrm{~A}$ and beta = 3 mathrm~A/s$\beta = 3 \mathrm{~A/s}$:
I = 20 + 3t$I = 20 + 3t$
Thus:
fracdqdt = 20 + 3t$\frac{dq}{dt} = 20 + 3t$
### Step 1: Integrate to Find Charge
To find the total charge crossing a section of wire from t = 0$t = 0$ to t = 20 mathrm~s$t = 20 \mathrm{~s}$:
int_0^q dq = int_0^20 (20 + 3t) \, dt$\int_{0}^{q} dq = \int_{0}^{20} (20 + 3t) \, dt$q = left[ 20t + frac3t^22 right]_0^20$q = \left[ 20t + \frac{3t^2}{2} \right]_{0}^{20}$q = 20(20) + frac3(20)^22$q = 20(20) + \frac{3(20)^2}{2}$q = 400 + frac3(400)2 = 400 + 600 = 1000 mathrm~C$q = 400 + \frac{3(400)}{2} = 400 + 600 = 1000 \mathrm{~C}$
Therefore, the charge crossed is 1000 mathrm~C$1000 \mathrm{~C}$.
### Pattern Recognition
Whenever current is given as a function of time I(t)$I(t)$, the total charge is simply the area under the I-t$I-t$ curve, which mathematically corresponds to the definite integral int_t_1^t_2 I(t) \, dt$\int_{t_1}^{t_2} I(t) \, dt$.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Physics: Current Electricity
Q57jee_main_2024_29_jan_morningKirchhoff's Laws and RC Circuits
A 16 \, Omega$16 \, \Omega$ wire is bend to form a square loop. A 9V battery with internal resistance 1 \, Omega$1 \, \Omega$ is connected across one of its sides. If a 4 \, mu mathrmF$4 \, \mu \mathrm{F}$ capacitor is connected across one of its diagonals, the energy stored by the capacitor will be fracx2 \, mu mathrmJ$\frac{x}{2} \, \mu \mathrm{J}$. where x = $x = $ _________.
Numerical Answer.Answer: 81 to 81
Solution
### Related Formula
Energy stored (U$U$) by a capacitor of capacitance C$C$ under steady state voltage V_C$V_C$:
U = frac12 C V_C^2$U = \frac{1}{2} C V_C^2$
### Core Logic
A wire of resistance 16 \, Omega$16 \, \Omega$ is bent into a square, so each of the 4 sides has a resistance of:
R_textside = frac164 = 4 \, Omega$R_{\text{side}} = \frac{16}{4} = 4 \, \Omega$
The battery is connected across one side. Let this side have resistance 4 \, Omega$4 \, \Omega$. The remaining three sides are connected in series, creating a parallel branch with a combined resistance of:
R_textseries = 4 + 4 + 4 = 12 \, Omega$R_{\text{series}} = 4 + 4 + 4 = 12 \, \Omega$Circuit network layout showing the square loop resistance divisions and diagonal capacitor connection for Q57
### Step 1: Calculate Equivalent Resistance and Circuit Current
The equivalent external resistance of the parallel loop branches is:
R_p = frac12 times 412 + 4 = frac4816 = 3 \, Omega$R_p = \frac{12 \times 4}{12 + 4} = \frac{48}{16} = 3 \, \Omega$
Including the battery's internal resistance (1 \, Omega$1 \, \Omega$), the total line current I$I$ leaving the battery is:
I = fracVR_p + r = frac93 + 1 = frac94 mathrm~A$I = \frac{V}{R_p + r} = \frac{9}{3 + 1} = \frac{9}{4} \mathrm{~A}$
### Step 2: Find Current through the Main Branches
Using the current divider rule, the current I_1$I_1$ flowing through the longer 12 \, Omega$12 \, \Omega$ branch is:
I_1 = I times frac412 + 4 = frac94 times frac416 = frac916 mathrm~A$I_1 = I \times \frac{4}{12 + 4} = \frac{9}{4} \times \frac{4}{16} = \frac{9}{16} \mathrm{~A}$
### Step 3: Find Potential Difference across the Diagonal
In a steady state, the capacitor acts as an open circuit. Let the diagonal link nodes be A$A$ and B$B$. The path contains two sides of the 12 \, Omega$12 \, \Omega$ branch (total resistance = 8 \, Omega$8 \, \Omega$):
V_C = V_A - V_B = I_1 times 8 = frac916 times 8 = frac92 mathrm~V$V_C = V_A - V_B = I_1 \times 8 = \frac{9}{16} \times 8 = \frac{9}{2} \mathrm{~V}$
### Step 4: Compute Stored Energy and Extract x
The stored energy U$U$ is:
U = frac12 times (4 \, mu mathrmF) times left(frac92right)^2 = frac12 times 4 times frac814 = frac812 \, mu mathrmJ$U = \frac{1}{2} \times (4 \, \mu \mathrm{F}) \times \left(\frac{9}{2}\right)^2 = \frac{1}{2} \times 4 \times \frac{81}{4} = \frac{81}{2} \, \mu \mathrm{J}$
Comparing this directly with the expression fracx2 \, mu mathrmJ$\frac{x}{2} \, \mu \mathrm{J}$:
x = 81$x = 81$
Therefore, the value of x$x$ is 81$81$.
### Pattern Recognition
Remember that capacitors act as standard open circuits when reaching steady-state DC conditions. Simply calculate the node potentials across the bridge connection points using standard current distribution laws first, then execute the energy equation.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Physics: Current Electricity
Class 12 Physics: Electrostatic Potential and Capacitance
Q48jee_main_2024_30_january_eveningPower Dissipation in Resistors
When a potential difference V$V$ is applied across a wire of resistance R$R$, it dissipates energy at a rate W$W$. If the wire is cut into two halves and these halves are connected mutually parallel across the same supply, the energy dissipation rate will become:
A.1 / 4 mathrmW$1 / 4 \mathrm{W}$
B.1 / 2 mathrmW$1 / 2 \mathrm{W}$
C.2 mathrm~W$2 \mathrm{~W}$
D.4 mathrm~W$4 \mathrm{~W}$
Solution
### Related Formula
P = fracV^2R_texteq$P = \frac{V^2}{R_{\text{eq}}}$
### Core Logic
Initially, the power (rate of energy dissipation) is W = fracV^2R$W = \frac{V^2}{R}$.
When the wire is cut into two halves, each half will have a resistance of fracR2$\frac{R}{2}$ (since resistance is directly proportional to length).
### Step 1: Equivalent Resistance
When these two halves (each of fracR2$\frac{R}{2}$) are connected in parallel, their equivalent resistance R_texteq$R_{\text{eq}}$ is:
R_texteq = fracleft(fracR2right) times left(fracR2right)fracR2 + fracR2 = fracR4$R_{\text{eq}} = \frac{\left(\frac{R}{2}\right) \times \left(\frac{R}{2}\right)}{\frac{R}{2} + \frac{R}{2}} = \frac{R}{4}$
### Step 2: New Power Dissipation
The new rate of energy dissipation W'$W'$ across the same potential difference V$V$ is:
W' = fracV^2R_texteq = fracV^2fracR4 = 4 fracV^2R$W' = \frac{V^2}{R_{\text{eq}}} = \frac{V^2}{\frac{R}{4}} = 4 \frac{V^2}{R}$W' = 4W$W' = 4W$
### Pattern Recognition
Cutting a resistor into n$n$ equal parts and connecting them in parallel reduces the total resistance by a factor of n^2$n^2$. Consequently, for a constant voltage supply, the power dissipated increases by a factor of n^2$n^2$.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Physics: Current Electricity
Two resistance of 100Omega$100\Omega$ and 200Omega$200\Omega$ are connected in series with a battery of 4 mathrm~V$4 \mathrm{~V}$ and negligible internal resistance. A voltmeter is used to measure voltage across 100Omega$100\Omega$ resistance, which gives reading as 1 mathrm~V$1 \mathrm{~V}$. The resistance of voltmeter must be ________ Omega$\Omega$.
Numerical Answer.Answer: 200 to 200
Solution
### Related Formula
V = I R_texteq$V = I R_{\text{eq}}$R_textparallel = fracR_1 R_2R_1 + R_2$R_{\text{parallel}} = \frac{R_1 R_2}{R_1 + R_2}$
### Core Logic
Voltmeter Resistance diagram for Q60 - JEE Main 2024 Evening
The voltmeter has some internal resistance R_v$R_v$ and is connected in parallel with the 100Omega$100\Omega$ resistor.
The equivalent resistance of this parallel combination is R_p = frac100 R_v100 + R_v$R_p = \frac{100 R_v}{100 + R_v}$.
This combination is in series with the 200Omega$200\Omega$ resistor. The total voltage applied is 4 mathrm~V$4 \mathrm{~V}$.
### Step 1: Set up Voltage Divider
The voltage across the parallel combination (the voltmeter reading) is 1 mathrm~V$1 \mathrm{~V}$.
Therefore, the voltage across the 200Omega$200\Omega$ resistor must be 4 mathrm~V - 1 mathrm~V = 3 mathrm~V$4 \mathrm{~V} - 1 \mathrm{~V} = 3 \mathrm{~V}$.
Using the voltage divider rule (or equating currents since they are in series):
I = fracV_200200 = frac3200 mathrm~A$I = \frac{V_{200}}{200} = \frac{3}{200} \mathrm{~A}$
### Step 2: Solve for Voltmeter Resistance
The current I$I$ also flows through the parallel combination R_p$R_p$:
V_p = I R_p$V_p = I R_p$1 = left(frac3200right) left( frac100 R_v100 + R_v right)$1 = \left(\frac{3}{200}\right) \left( \frac{100 R_v}{100 + R_v} \right)$200 (100 + R_v) = 300 R_v$200 (100 + R_v) = 300 R_v$20000 + 200 R_v = 300 R_v$20000 + 200 R_v = 300 R_v$100 R_v = 20000$100 R_v = 20000$R_v = 200 Omega$R_v = 200 \Omega$
### Pattern Recognition
If the voltage splits as 1mathrmV$1\mathrm{V}$ to 3mathrmV$3\mathrm{V}$, the resistances must be in a 1:3$1:3$ ratio. So R_p = 200 / 3$R_p = 200 / 3$. Equating 100 R_v / (100+R_v) = 200/3$100 R_v / (100+R_v) = 200/3$ instantly gives R_v = 200$R_v = 200$.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Physics: Current Electricity
Q33jee_main_2024_30_jan_morningResistors in Series and Voltage Dividers
A potential divider circuit is shown in figure. The output voltage V_0$V_0$ is
Circuit containing multiple resistors in series and parallel calculating a specific output voltage.
A.4 mathrm~V$4 \mathrm{~V}$
B.2 mathrm~mV$2 \mathrm{~mV}$
C.0.5 mathrm~V$0.5 \mathrm{~V}$
D.12 mathrm~mV$12 \mathrm{~mV}$
Solution
### Related Formula
V = IR$V = IR$R_texteq = R_1 + R_2 + dots + R_n quad (textfor series)$R_{\text{eq}} = R_1 + R_2 + \dots + R_n \quad (\text{for series})$
### Core Logic
Observe the circuit diagram. The total equivalent resistance R_texteq$R_{\text{eq}}$ of the series network must be calculated by summing all the resistance values shown in the main branch.
### Step 1: Calculate Total Resistance and Current
From the given network, assuming the total series resistance is 4000 \,Omega$4000 \,\Omega$ (comprising the 3.3mathrmkOmega$3.3\mathrm{k}\Omega$ resistor and seven 100\,Omega$100\,\Omega$ resistors).
R_texteq = 4000 \,Omega$R_{\text{eq}} = 4000 \,\Omega$
The total voltage applied across the network is 4 mathrm~V$4 \mathrm{~V}$.
i = fracVR_texteq = frac44000 = frac11000 mathrm~A$i = \frac{V}{R_{\text{eq}}} = \frac{4}{4000} = \frac{1}{1000} \mathrm{~A}$
### Step 2: Calculate Output Voltage
The output voltage V_0$V_0$ is tapped across five 100 \,Omega$100 \,\Omega$ resistors.
R_textout = 5 times 100 \,Omega = 500 \,Omega$R_{\text{out}} = 5 \times 100 \,\Omega = 500 \,\Omega$
Thus, the output voltage is:
V_0 = i cdot R_textout = left(frac11000right) times 500 = 0.5 mathrm~V$V_0 = i \cdot R_{\text{out}} = \left(\frac{1}{1000}\right) \times 500 = 0.5 \mathrm{~V}$
### Pattern Recognition
A potential divider simply scales the input voltage by the fraction of the resistance tapped over the total resistance: V_0 = V_in times (R_texttap / R_texttotal)$V_0 = V_{in} \times (R_{\text{tap}} / R_{\text{total}})$. Standard DC circuit division.
### Evaluation Rubric / Model Answer
null
### Chapter Mix
Class 12 Physics: Current Electricity
More Current Electricity Questions — jee_main_2024_29_january_evening
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