UPUMCWA UPCMET 2016 Syllabus MBBS UP Combined Medical Entrance Test : Uttar Pradesh
Organisation : U.P. Unaided Medical Colleges Welfare Association Uttar Pradesh
Announcement : Syllabus
Entrance Exam : UP Combined Medical Entrance Test (UPCMET) 2016
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Syllabus : https://www.entrance.net.in/uploads/26-uginfo2016.pdf
Home Page : http://upumcwa.org/index_ug.htm
Syllabus :
Physical and Biological Sciences :
Paper-I :
(A) PHYSICAL SCIENCES :
Physics :
(a) Measurement and Kinematics :
1. Estimation of percentage error in the result of an experiment
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2. Dimensional analysis : Dimension of a physical quantity M,L,T,q, (Temperature), Dimensional balance of any equation.
3. Motion along straight line path : Time displacement, time-velocity and time-acceleration graphs. Interrelationship among the graphs.
4. Motion in a plane : Vector addition and subtraction (Laws of Polygon to be used) (AB+BC=AC), Graphical deduction has to be emphasized. Multiplication of a vector by a scalar. Uniform motion on a circular path magnitude of centripetal acceleration and force (Centrifugal force does not exist in inertial frame). Motion under a uniform acceleration along a direction other than that of the initial velocity (motion of projectile under gravity 2 is included herein interpretation of the vector form of the equation v=u + at and s = ut + ½ at
(b) Mechanics :
1. Newton’s Laws of Motion : the first law (Galileo’s Law of Inertia) and the third law (F = -F ) are obtained from the second law (a=F/m), variable force, impulse (F.Dt), conservation of momentum, Principle of jet propulsion.
3. Work Energy: Derivation of expression for kinetic energy (1/2mV ) and 1/2Iw) respectively from work done by a force and by a couple. Potential energy for a general Fx relation (using the method of area under the curve) for a constant force (e.g.mgh) and for spring 1/2kx . Conservation of mechanical energy. Elastic and Inelastic collisions (no description). Law of mechanical energy in inelastic collisions.
4. Universal Gravitation: Motion of planets Kepler’s laws. Law of gravitation in terms of central force dependence of force on and inverse of square of distance (no derivation). Planets, orbital motion and time period, concepts of weightlessness. Gravitational field (nt/Kg) and potential (J/Kg). Height attained by the projectile, escape velocity.
5. Simple harmonic motion: Pure kinetic motion in terms of projection of uniform circular motion. Formula y=A sin 2 wt. Magnitude of acceleration is -w times the displacement, kinetic description that motion in which the force is 2 k times the displacement. Relation w = k/m and t = 2pÖ m/k and its uses in (i) Simple Pendulum
(ii) Oscillation in an ideal spring. Time displacement graph, time period, frequency, phase. Total energy in terms of square of amplitude, conversion of energy in the form of potential and kinetic energies, dissipation and damping.
6. Forced oscillation and resonance: Elementry concept of forced oscillations, cases of resonance examples from mechanics, sound and radio etc.
(c) Wave Motion and Sound :
1. Speed of mechanical waves : Newton’s formula v=EÖd (no derivation) for longitudinal waves. Order of magnitude of v in various media. Application to gases, Laplace’s correction, effect of temperature and pressure for waves on string v =(ÖT/m) (no derivation).
2. Progressive wave : Equation for a simple harmonic progressive wave, phases and phase difference, Wave front graphical representation of particle velocity against x and t. Qualitative picture of pressure variations in longitudinal waves, intensity dependence on square of amplitude (no derivation).
3. Reflection and refraction of waves : Demonstration of characteristics of wave motion with the help of pulse on a string and on water. Mutual independence of various waves in the same medium. Partial reflection and transmission at the interface of two media, Explanation of reflection and refraction on the basis of secondary wavelets and new wave fronts
4. Superposition of waves : Interference in space due to two sources, phenomenon of beats, beat frequency equals the difference of parent frequencies.
5. Stationary waves : Bounded medium, stationary waves, nodes and antinodes, Characteristic frequencies of vibration of a bounded medium. Cases of string and air columns (excluding end correction etc. Sonometer, Melde’s experiment, Resonance column and Kundt’s tube.
6. Doppler’s Principle : Doppler effect due to the motion of the source and due to the motion of the observer.
(d) General Properties of Matter :
1. Kinetic theory and ideal gases: Molecular agitation, deduction of pressure of an ideal gas, Boyle’s Law. Kinetic theory concepts of thermal equilibrium and temperature, Perfect gas equation, deviation from the ideal gas equation at high pressure and low temperature, concepts of finite size of molecules and their mutual interactions. Distinction between gas and vapour, critical temperature.
2. Kinetic models for liquids and solids : Intermolecular forces and potential energy curve. Molecular models for the liquids and solids, Elementary explanation for thermal expansion, fusion. Vaporization, boiling and latent heats.
3. Elasticity : Longitudinal strain, stress and modulus of elasticity. Explanation on the atomic models of solids. Estimation of interatomic force constant. Bulk modulus and rigidity (Only elementry ideas).
4. Surface tension : Surface tension, surface energy. Elementry explanation on the basis of inter molecular forces. Rise of liquid in a capillary tube.
5. Flow of liquids : Ideal fluids, Bernaulli’s equation and its application. Viscous fluids (elementry concepts only), viscous force on a solid moving in fluid, Stake’s Principle (no derivation), terminal Velocity.
Chemistry :
Section A :
General Chemistry :
1. Discovery & Properties of electron, proton, neutron, Elementary ideas of Binding Energy of Nucleus, Electronic Configuration, electronic shells, subshells, Quantum number, Pauli’s exclusion principle
2. Detailed Study of Electrovalence, covalence(including Kossels theory) and coordinate valence bonds and Electronics Structure of compounds.
3. Radioactivity, Natural & Artificial disintegration, half life, fission and fusion, isotopes and isobars, radioactive isotopes and their uses
4. Electrode potential and electrochemical series
5. Oxidation & reduction reactions, oxidation number, balancing of equations by oxidation number and electron method
6. Law of gases, gas equation, Dalton Law of partial pressure, Simple numericals based on Graham’s Law of diffusion
7. Volumetric analysis and qualitative analysis
Section B :
Inorganic Chemistry :
1. Detailed study of Mendeleefs periodic table (Excluding historical backgrounds). Position of the elements in the periodic table on the basis of atomic structure, modern periodic table, Periodic properties of elements (Atomic radius, ionisation potential, electron affinity) (Only definitions)
2. Hydrogen and its Compounds-Position of Hydrogen in Periodic table, isotopes of Hydrogen, Deuterium, Heavy Water, Laboratory methods of the preparation of Hydrogen Peroxide, outline of industrial preparation, properties, uses and structure of H O 2 2.
3. Studies of First group elements (Alkali metals)-Position of Na, K in the Periodic table on the basis of electronic configuration, Laboratory method for the preparation of Na Co NaOH, NaNH , (HPO ), H O microcosmic salt, outline of their industrial preparation, properties and uses.
4. Studies of second group elements (Alkaline earth metals)-Position of Mg, Ca, Sr, Ba in the periodic table on the basis of configuration. Preparation of Plaster of Paris (CaSo ) H O, its properties and uses, outline of the industrial preparation of Cement and its uses.
5. Studies of third group elements – Properties of Al, its uses and metallurgy, method of preparation of Anhydrous AlCl Alum-their properties and uses. 3,
6. Studies of fourth group of elements- Position of C and Pb in the periodic table on the basis of electronic configuration, Fuel gases, (oil gas, water gas, coal gas, petrol gas) methods of preparation, outline of industrial preparation and uses. Outline of industrial preparation of glass and uses. Preparation of SnCl its properties and 2 uses, preparation of white lead, red lead, basic lead acetate their properties and uses.
7. Studies of fifth group elements-Position of N, P, As, Sb, Bi in the Periodic table on the basis of electronic configuration. Preparation, properties and uses of NH HNO , N O, HNO P PH Orthphosphoric Acid, Arsenious oxide, Methods of Industrial Preparation of HNO , Nitrogenous and Phosphate Fertilizer.
8. Studies of Sixth group elements-Methods of preparation, industrial preparation, uses and structure of O & 3 H SO .
9. Studies of Seventh group elements-position of Cl, Br, I in the periodic Table on the basis of electron configuration. Methods of preparation, Industrial preparation, properties and uses of Cl Br , I & Bleaching 2, 2 2 Powder.
10. Inert Gases Position in Periodic Table, history of discovery, general characteristics uses.
11 Transition elements – (1) General studies-Position in periodic table, properties (2) Position of IB, IIB & VIII group elements in the periodic Table (3)Position of Cu Ag on the basis of electronic configuration. Properties, preparation and uses of Cu Cl and AgNO (4) Position of Zn, Cd on the basis of electronic configuration, 2 2 3 Methods of preparation, properties and uses of calomel, corrosive sublimate, Zncl , ZnO (5) Position of Fe in 2 2 the periodic Table on the basis of electronic configuration, metallurgy and uses. Industrial product of Steel and Steel Industry of India. Methods of preparations, properties and uses of Mohr’s salt & Ferric Chloride.
Section C :
Physical Chemistry :
1. Chemical Equilibrium : Law of Mass action, Velocity constant and Equilibrium constant (only in homogeneous gas system. Qualitative derivation of Le Chateriier’s Principle.
2. Principle of electrolytic dissociation, Ostwald dilution Law, Degree of dissociation, dissociation constant, Hydrolysis, neutralisation, Strength of acids and bases, pH, Buffer solution, Qualitative description of acid bases indicators, solubility product and common ion effect (excluding the determination of constants).
3. Different methods to represent concentration of solution properties of solution, lowering of vapour pressure by mixing a solute, Osmosis and determination of Osmotic pressure by Berkeley and Hartley’s method, determination of molecular weight of non-volatile substances by the elevation of boiling point and depression of freezing point (excluding the derivation of formulae).
4. Distribution of a solute in the non mixing liquid (excluding association, dissociation and complexing agents.
5. Catalyst: Properties, homogenous and heterogeneous catalyst, intermediate theory and modern absorption theory and Enzyme catalyst.
6. Definition of colloidal solution and its important properties(excluding electronic properties)
7. Thermo chemistry First law of thermo-dynamics, Definition and concept of internal Energy, heat of reaction, Heat of combustion, heat of formation, Heat of neutralization, Hess’s Law and numerical problem based on it.