In the diagrams, all light bulbs are identical and all emf sources are ideal and identical. In which circuit (given in option) will each bulb glow with the same brightness as in the circuit shown?

Consider the shown circuit. The capacitor is uncharged when the swith is closed at time t=0. Which of the circuit given in option is equivalent to the shown circuit as t approaches infinity?

If a number of bulbs of different wattages are joined in parallel With a voltage source, which bulb will glow With maximum brightness?

There are 3 oranges, 5 apples and 6 mangoes in a fuit basket (all fruits of same kind are identical). Number of ways in which fruits can be selected from the basket, is

Six similar bulbs are connected as shown in the figure with a DC source of emf E, and zero internal resistance. The ratio of power consumption by the bulbs when (i) all are glowing and (ii) in the situation when two from section A and one from section B are glowing, will be : (a) 2: 1 (b) 4 : 9 (c) 9 : 4 (d) 1 : 2

The circuit shown has an idel ammeter with zero resistance and four identical light bulbs which are initially illuminated. A person removes the bulb R_(4) from it s socket there by permanently breaking the electrical circuit at that point. Which statement is true about the circuit after removing the bulb?

Two identical incandescent light bulbs are connected as shown in figure. When the circuit is connected with an A.C. voltage source of frequency f, which of the following observation will be correct ?

Given below in the diagram of bacteriophage. In which one of the options all the four parts a, B , C and D are correct ?

A battery consist of a variable number 'n' of identical cells (having internal resistance 'r' each) which are connected in series. The tem1inals of the battery are short-circuited and the current I is measured. Which of the graphs shows the correct relationship between I and n ?

An experimental setup of verification of photoelectric effect is shown in the diagram. The voltage across the electrode is measured with the help of an ideal voltmetar, and which can be varied by moving jockey 'J' on the potentiometer wire. The battery used in potentiometer circuit is of 20 V and its internal resistance is 2omega . The resistance of 100 cm long potentiometer wire is 8 omega . The photo current is measured with the help of an ideal ammeter. Two plates of potassium oxide of area 50 cm^(2) at separation 0.5 mm are used in the vacuum tube. Photo current in the circuit is very small so we can treat potentiometer circuit an indepdent circuit. The wavelength of various colours is as follows : |{:("Light",underset("Violet")(1),underset("Blue")(2),underset("Green")(3),underset("Yellow")(4),underset("Orange")(5),underset("Red")(6)),(lambda "in" Årarr,4000-4500,4500-5000,5000-5500,5500-6000,6000-6500,6500-7000):}| It is found that ammeter current remians unchanged (2muA) even when the jockey is moved from the 'P' to the middle point of the potentiometer wire. Assuming all the incident photons eject electron and the power of the light incident is 4 xx 10^(-6) W . Then colour of the incident light is :

An experimental setup of verification of photoelectric effect is shown in the diagram. The voltage across the electrode is measured with the help of an ideal voltmetar, and which can be varied by moving jockey 'J' on the potentiometer wire. The battery used in potentiometer circuit is of 20 V and its internal resistance is 2omega . The resistance of 100 cm long potentiometer wire is 8 omega . The photo current is measured with the help of an ideal ammeter. Two plates of potassium oxide of area 50 cm^(2) at separation 0.5 mm are used in the vacuum tube. Photo current in the circuit is very small so we can treat potentiometer circuit an indepdent circuit. The wavelength of various colours is as follows : |{:("Light",underset("Violet")(1),underset("Blue")(2),underset("Green")(3),underset("Yellow")(4),underset("Orange")(5),underset("Red")(6)),(lambda "in" Årarr,4000-4500,4500-5000,5000-5500,5500-6000,6000-6500,6500-7000):}| When other light falls on the anode plate the ammeter reading remains zero till, jockey till, jockey is moved from the end P to the middle point on the wire PQ. Thereafter the deflection is recorded in the ammeter. The maximum kinetic energy of the emitted electron is :