BITSAT Syllabus 2024: Physics, Chemistry, Mathematics, & Biology

BITS, Pilani organizes this university-level engineering entrance exam for admissions to undergraduate engineering courses at its four campuses. The courses under this are BE, BPharm, and MSc programs. This exam is conducted annually, and approximately 3 lakh students appear in it. The four campuses of BITS are located in Pilani, Goa, Hyderabad, and Dubai. This article will give you complete information regarding the BITSAT Syllabus 2024.

BITSAT Syllabus 2024 [Subject-Wise]

If you plan to appear for the BITSAT exam, you must stay updated with the examination syllabus. Knowing the syllabus saves time as the candidates learn what must be studied. The syllabus is divided into five parts. The complete part-wise syllabus is given below:

  • Part 1: Physics
  • Part 2: Chemistry
  • Part 3: English
  • Part 4: Mathematics
  • Part 5: Biology

Physics:

1. Units & Measurement
Units (Different systems of units, SI units, fundamental and derived units)
Dimensional Analysis
Precision and significant figures
Fundamental measurements in Physics (Vernier calipers, screw gauge, Physical balance, etc.)
2. Kinematics
Properties of vectors
Position, velocity, and acceleration vectors
Motion with constant acceleration
Projectile motion
Uniform circular motion
Relative motion
3. Newton’s Laws of Motion
Newton’s laws (free body diagram, resolution of forces)
Motion on an inclined plane
The motion of blocks with pulley systems
Circular motion – centripetal force
4Impulse and Momentum
Definition of impulse and momentum
Conservation of momentum
Collisions
The momentum of a system of particles
Center of mass
5. Work and Energy
Work done by a force
Kinetic energy and work-energy theorem
Power
Conservative forces and potential energy
Conservation of mechanical energy
6. Rotational Motion
Description of rotation (angular displacement, angular velocity, and angular acceleration)
Rotational motion with constant angular acceleration
Moment of inertia, Parallel and perpendicular axes theorems, rotational kinetic energy
Torque and angular momentum
Conservation of angular momentum
Rolling motion
7. Gravitation
Newton’s law of gravitation
Gravitational potential energy, Escape velocity
The motion of planets – Kepler’s laws, satellite motion
8. Mechanics of Solids and Fluids
Elasticity
Pressure, density, and Archimedes’ principle
Viscosity and Surface Tension
Bernoulli’s theorem
9. Oscillations
Kinematics of simple harmonic motion
Spring mass system, simple and compound pendulum
Forced & damped oscillations, resonance
10. Waves
Progressive sinusoidal waves
Standing waves in strings and pipes
Superposition of waves, beats
Doppler Effect
11. Heat and Thermodynamics
Kinetic theory of gases
Thermal equilibrium and temperature
Specific heat, Heat Transfer – Conduction, convection and radiation, thermal conductivity, Newton’s law of cooling
Work, heat and the first law of thermodynamics
2nd law of thermodynamics, Carnot engine – Efficiency and Coefficient of performance
12. Electrostatics
Coulomb’s law
Electric field (discrete and continuous charge distributions)
Electrostatic potential and Electrostatic potential energy
Gauss’ law and its applications
Electric dipole
Capacitance and dielectrics (parallel plate capacitor, capacitors in series and parallel)
13. Current Electricity
Ohm’s law, Joule heating
D.C circuits – Resistors and cells in series and parallel, Kirchoff’s laws, potentiometer and Wheatstone bridge,
Electrical Resistance (Resistivity, origin, and temperature dependence of resistivity).
14. Magnetic Effect of Current
Biot-Savart’s law and its applications
Ampere’s law and its applications
Lorentz force, force on current-carrying conductors in a magnetic field
The magnetic moment of a current loop, torque on a current loop, Galvanometer and its conversion to voltmeter and ammeter
15. Electromagnetic Induction
Faraday’s law, Lenz’s law, eddy currents
Self and mutual inductance
Transformers and generators
Alternating current (peak and RMS value)
AC circuits, LCR circuits
16. Optics
Laws of reflection and refraction
Lenses and mirrors
Optical instruments – telescope and microscope
Interference – Huygen’s principle, Young’s double-slit experiment
Interference in thin films
Diffraction due to a single slit
Electromagnetic waves and their characteristics (only qualitative ideas), Electromagnetic spectrum
Polarization – states of polarization, Malus’ law, Brewster’s law
17. Modern Physics
Dual nature of light and matter – Photoelectric effect, De Broglie wavelength
Atomic models – Rutherford’s experiment, Bohr’s atomic model
Hydrogen atom spectrum
Radioactivity
Nuclear reactions: Fission and fusion, binding energy
18. Electronic Devices 
Energy bands in solids (qualitative ideas only), conductors, insulators, and semiconductors;
Semiconductor diode – I-V characteristics in forward and reverse bias, diode as a rectifier; I-V characteristics of LED, photodiode, solar cell, and Zener diode; Zener diode as a voltage regulator.
Junction transistor, transistor action, characteristics of a transistor; transistor as an amplifier (common emitter configuration) and oscillator
Logic gates (OR, AND, NOT, NAND and NOR). Transistor as a switch.

Chemistry:

1. the States of Matter
Measurement: Physical quantities and SI units, Dimensional analysis, Precision, Significant figures.
Chemical reactions: Laws of chemical combination, Dalton’s atomic theory; Mole concept; Atomic, molecular and molar masses; Percentage composition empirical & molecular formula; Balanced chemical equations & stoichiometry
Three states of matter, intermolecular interactions, types of bonding, melting and boiling points Gaseous state: Gas Laws, ideal behavior, ideal gas equation, empirical derivation of gas equation, Avogadro number, Deviation from ideal behavior – Critical temperature, Liquefaction of gases, van der Waals equation.
Liquid state: Vapour pressure, surface tension, viscosity.
Solid-state: Classification; Space lattices & crystal systems; Unit cell in two dimensional and three-dimensional lattices, calculation of density of unit cell – Cubic & hexagonal systems; Close packing; Crystal structures: Simple AB and AB2 type ionic crystals, covalent crystals – diamond & graphite, metals. Voids, number of atoms per unit cell in a cubic unit cell, ImperfectionsPoint defects, non-stoichiometric crystals; Electrical, magnetic, and dielectric properties; Amorphous solids – qualitative description. Band theory of metals, conductors, semiconductors, and insulators, and n- and p-type semiconductors.
2. Atomic Structure
Introduction: Subatomic particles; Atomic number, isotopes, and isobars, Thompson’s model and its limitations, Rutherford’s picture of the atom and its limitations; Hydrogen atom spectrum and Bohr model and its limitations.
Quantum mechanics: Wave-particle duality – de Broglie relation, Uncertainty principle; Hydrogen atom: Quantum numbers and wavefunctions, atomic orbitals and their shapes (s, p, and d), Spin quantum number.
Many electron atoms: Pauli exclusion principle; Aufbau principle and the electronic configuration of atoms, Hund’s rule.
Periodicity: Brief history of the development of periodic tables Periodic law and the modern periodic table; Types of elements: s, p, d, and f blocks; Periodic trends: ionization energy, atomic, and ionic radii, inter gas radii, electron affinity, electronegativity, and valency. Nomenclature of elements with atomic number greater than 100.
3. Chemical Bonding & Molecular Structure
Valence electrons, Ionic Bond: Lattice Energy and Born-Haber cycle; Covalent character of ionic bonds and polar character of covalent bond, bond parameters
Molecular Structure: Lewis picture & resonance structures, VSEPR model & molecular shapes
Covalent Bond: Valence Bond Theory- Orbital overlap, Directionality of bonds & hybridization (s, p & d orbitals only), Resonance; Molecular orbital theory- Methodology, Orbital energy level diagram, Bond order, Magnetic properties for homonuclear diatomic species (qualitative idea only).
Dipole moments; Hydrogen Bond
4. Thermodynamics
Basic Concepts: Systems and surroundings; State functions; Intensive & Extensive Properties; Zeroth Law and Temperature
First Law of Thermodynamics: Work, internal energy, heat, enthalpy, heat capacities, and specific heats, measurements of ∆U and ∆H, Enthalpies of formation, phase transformation, ionization, electron gain; Thermochemistry; Hess’s Law, Enthalpy of bond dissociation, combustion, atomization, sublimation, solution, and dilution
Second Law: Spontaneous and reversible processes; entropy; Gibbs free energy related to spontaneity and non-spontaneity, non-mechanical work; Standard free energies of formation, free energy change, and chemical equilibrium
Third Law: Introduction
5. Physical and Chemical Equilibria
Concentration Units: Mole Fraction, Molarity, and Molality
Solutions: Solubility of solids and gases in liquids, Vapour Pressure, Raoult’s law, Relative lowering of vapor pressure, depression in freezing point; elevation in boiling point; osmotic pressure, determination of molecular mass; solid solutions, abnormal molecular mass, can’t Hoff factor. Equilibrium: Dynamic nature of equilibrium, the law of mass action
Physical Equilibrium: Equilibria involving physical changes (solid-liquid, liquid-gas, solid-gas), Surface chemistry, Adsorption, Physical and Chemical adsorption, Langmuir Isotherm, Colloids and emulsion, classification, preparation, uses.
Chemical Equilibria: Equilibrium constants (KP, KC), Factors affecting equilibrium, LeChatelier’s principle.
Ionic Equilibria: Strong and Weak electrolytes, Acids and Bases (Arrhenius, Lewis, Lowry, and Bronsted) and their dissociation; degree of ionization, Ionization of Water; ionization of polybasic acids, pH; Buffer solutions; Henderson equation, Acid-base titrations; Hydrolysis; Solubility Product of Sparingly Soluble Salts; Common Ion Effect.
Factors Affecting Equilibria: Concentration, Temperature, Pressure, Catalysts, Significance of ΔG and ΔG0 in Chemical Equilibria.
6. Electrochemistry
Redox Reactions: Oxidation-reduction reactions (electron transfer concept); Oxidation number; Balancing of redox reactions; Electrochemical cells and cell reactions; Standard electrode potentials; EMF of Galvanic cells; Nernst equation; Factors affecting the electrode potential; Gibbs energy change and cell potential; Secondary cells; dry cells, Fuel cells; Corrosion and its prevention.
Electrolytic Conduction: Electrolytic Conductance; Specific and molar conductivities; variations of conductivity with concentration, Kolhrausch’s Law and its application, Electrolysis, Faraday’s laws of electrolysis; Electrode potential and electrolysis, Commercial production of the chemicals, NaOH, Na, Al.
7. Chemical Kinetics
Aspects of Kinetics: Rate and Rate expression of a reaction; Rate constant; Order and molecularity of the reaction; Integrated rate expressions and half-life for zero and first-order reactions
Factor Affecting the Rate of the Reactions: Concentration of the reactants, catalyst; the size of particles, the Temperature dependence of rate constant concept of collision theory (elementary idea, no mathematical treatment); Activation energy
Surface Chemistry: Adsorption – physisorption and chemisorption; factors affecting adsorption of gasses on solids; catalysis: homogeneous and heterogeneous, activity and selectivity: enzyme catalysis, colloidal state: the distinction between true solutions, colloids, and suspensions; lyophilic, lyophobic multimolecular and macromolecular colloids; properties of colloids; Tyndall effect, Brownian movement, electrophoresis, coagulation; emulsions–types of emulsions.
8. Hydrogen and s-block elements
Hydrogen: Element: unique position in the periodic table, occurrence, isotopes; Dihydrogen: preparation, properties, reactions, and uses; Molecular, saline, ionic, covalent, interstitial hydrides; Water: Properties; Structure and aggregation of water molecules; Heavy water; Hydrogen peroxide: preparation, reaction, structure & use, Hydrogen as a fuel.
s-block elements: Abundance and occurrence; Anomalous properties of the first elements in each group; diagonal relationships; trends in the variation of properties (ionization energy, atomic & ionic radii).
Alkali metals: Lithium, sodium, and potassium: occurrence, extraction, reactivity, and electrode potentials; Biological importance; Reactions with oxygen, hydrogen, halogens water; Basic nature of oxides and hydroxides; Halides; Properties and uses of compounds such as NaCl, Na2CO3, NaHCO3, NaOH, KCl, and KOH.
Alkaline earth metals: Magnesium and calcium: Occurrence, extraction, reactivity and electrode potentials; Reactions with O2, H2O, H2, and halogens; Solubility and thermal stability of oxo salts; Biological importance of Ca and Mg; Preparation, properties, and uses of important compounds such as CaO, Ca(OH)2, plaster of Paris, MgSO4, MgCl2, CaCO3, and CaSO4.
9. p- d- and f-block elements
General: Abundance, distribution, physical and chemical properties, isolation and uses of elements; Trends in chemical reactivity of elements of a group; electronic configuration, oxidation states; anomalous properties of the first element of each group.
Group 13 elements: Boron; Properties and uses of borax, boric acid, boron hydrides & halides. The reaction of aluminum with acids and alkalis;
Group 14 elements: Carbon: carbon catenation, physical & chemical properties, uses, allotropes (graphite, diamond, fullerenes), oxides, halides and sulfides, carbides; Silicon: Silica, silicates, silicone, silicon tetrachloride, Zeolites, and their uses
Group 15 elements: Dinitrogen; Preparation, reactivity, and uses of nitrogen; Industrial and biological nitrogen fixation; Compound of nitrogen; Ammonia: Haber’s process, properties, and reactions; Oxides of nitrogen and their structures; Properties and Ostwald’s process of nitric acid production; Fertilizers – NPK type; Production of phosphorus; Allotropes of phosphorus; Preparation, structure, and properties of hydrides, oxides, oxoacids (elementary idea only) and halides of phosphorus, phosphine.
Group 16 elements: Isolation and chemical reactivity of dioxygen; Acidic, basic, and amphoteric oxides; Preparation, structure, and properties of ozone; Allotropes of sulfur; Preparation/production properties and uses of sulfur dioxide and sulphuric acid; Structure and properties of oxides, oxoacids (structures only).
Group 17 and group 18 elements: Structure and properties of hydrides, oxides, oxoacids of halogens (structures only); preparation, properties & uses of chlorine & HCl; Inter halogen compounds; Bleaching Powder; Uses of Group 18 elements, Preparation, structure, and reactions of xenon fluorides, oxides, and oxoacids.
d-Block elements: General trends in the chemistry of first-row transition elements; Metallic character; Oxidation state; ionization enthalpy; Ionic radii; Color; Catalytic properties; Magnetic properties; Interstitial compounds; Occurrence and extraction of iron, copper, silver, zinc, and mercury; Alloy formation; Steel and some important alloys; preparation and properties of K2Cr2O7, KMnO4.
f-Block elements: Lanthanoids and actinoids; Oxidation states and chemical reactivity of lanthanoids compounds; Lanthanide contraction and its consequences, Comparison of actinoids and lanthanoids.
Coordination Compounds: Coordination number; Ligands; Werner’s coordination theory; IUPAC nomenclature; Application and importance of coordination compounds (in qualitative analysis, extraction of metals and biological systems e.g. chlorophyll, vitamin B12, and hemoglobin); Bonding: Valence-bond approach, Crystal field theory (qualitative); Isomerism including stereoisomerism.
10. Principles of Organic Chemistry and Hydrocarbons
Classification: General Introduction, classification based on functional groups, trivial and IUPAC nomenclature. Methods of purification: qualitative and quantitative,
Electronic displacement in a covalent bond: Inductive, resonance effects, and hyperconjugation; free radicals; carbocations, carbanions, nucleophiles, and electrophiles; types of organic reactions, free radial halogenations.
Alkanes: Structural isomerism, general properties, and chemical reactions, free medical halogenation, combustion, and pyrolysis.
Alkenes and alkynes: General methods of preparation and reactions, physical properties, electrophilic and free radical additions, acidic character of alkynes and (1,2 and 1,4) addition to dienes
Aromatic hydrocarbons: Sources; properties; isomerism; resonance delocalization; aromaticity; polynuclear hydrocarbons; IUPAC nomenclature; mechanism of electrophilic substitution reaction, directive influence and effect of substituents on reactivity; carcinogenicity and toxicity.
Haloalkanes and haloarenes: Physical properties, nomenclature, optical rotation, chemical reactions, and mechanism of substitution reaction. Uses and environmental effects; di, tri, tetrachloromethane, iodoform, freon, and DDT.
11. Stereochemistry
Conformations: Ethane conformations; Newman and Sawhorse projections.
Geometrical isomerism in alkenes
12. Organic Compounds with Functional Groups Containing Oxygen and Nitrogen
General: Nomenclature, electronic structure, important methods of preparation, identification, important reactions, physical and chemical properties, uses of alcohols, phenols, ethers, aldehydes, ketones, carboxylic acids, nitro compounds, amines, diazonium salts, cyanides, and isocyanides.
Specific: Reactivity of -hydrogen in carbonyl compounds, the effect of substituents on alpha-carbon on acid strength, comparative reactivity of acid derivatives, mechanism of nucleophilic addition and dehydration, the basic character of amines, methods of preparation, and their separation, importance of diazonium salts in synthetic organic chemistry.
13. Biological, Industrial and Environmental chemistry
Carbohydrates: Classification; Monosaccharides; Structures of pentoses and hexoses; Simple chemical reactions of glucose, Disaccharides: reducing and non-reducing sugars – sucrose, maltose, and lactose; Polysaccharides: elementary idea of structures of starch, cellulose, and glycogen.
Proteins: Amino acids; Peptide bond; Polypeptides; Primary structure of proteins; Simple idea of secondary, tertiary, and quaternary structures of proteins; Denaturation of proteins and enzymes.
Nucleic Acids: Types of nucleic acids; Primary building blocks of nucleic acids (chemical composition of DNA & RNA); Primary structure of DNA and its double helix; Replication; Transcription and protein synthesis; Genetic code.
Vitamins: Classification, structure, functions in biosystems; Hormones
Polymers: Classification of polymers; General methods of polymerization; Molecular mass of polymers; Biopolymers and biodegradable polymers; methods of polymerization (free radical, cationic and anionic addition polymerizations); Copolymerization: Natural rubber; Vulcanization of rubber; Synthetic rubbers. Condensation polymers.
Pollution: Environmental pollutants; soil, water, and air pollution; Chemical reactions in the atmosphere; Smog; Major atmospheric pollutants; Acid rain; Ozone and its reactions; Depletion of the ozone layer and its effects; Industrial air pollution; Greenhouse effect and global warming; Green Chemistry, study for control of environmental pollution
Chemicals in medicine, health-care and food: Analgesics, Tranquilizers, antiseptics, disinfectants, anti-microbials, anti-fertility drugs, antihistamines, antibiotics, antacids; Preservatives, artificial sweetening agents, antioxidants, soaps, and detergents.
14. Theoretical Principles of Experimental Chemistry
Volumetric Analysis: Principles; Standard solutions of sodium carbonate and oxalic acid; Acid-base titrations; Redox reactions involving KI, H2SO4, Na2SO3, Na2S2O3and H2S; Potassium permanganate in acidic, basic, and neutral media; Titrations of oxalic acid, ferrous ammonium sulfate with KMnO4, K2 Cr2O7/Na2S2O3, Cu(II)/Na2S2O3.
Qualitative analysis of Inorganic Salts: Principles in the determination of the cations Pb2+, Cu2+, As3+, Mn2+, Zn2+, Co2+, Ca2+, Sr2+, Ba2+, Mg2+, NH4+, Fe3+, Ni2+ and the anions CO32-, S2-, SO42-, SO32-, NO2, NO3, Cl, Br, I, PO43-, CH3COO, C2O42-.
Physical Chemistry Experiments: preparation and crystallization of alum, copper sulfate. Benzoic acid ferrous sulfate, double salt of alum and ferrous sulfate, potassium ferric sulfate; Temperature vs. solubility; Study of pH charges by common ion effect in case of weak acids and weak bases; pH measurements of some solutions obtained from fruit juices, solutions of known and varied concentrations of acids, bases and salts using pH paper or universal indicator; Lyophilic and lyophobic sols; Dialysis; Role of emulsifying agents in emulsification. Equilibrium studies involving ferric and thiocyanate ions (ii) [Co(H2O)6] 2+ and chloride ions; Enthalpy determination for strong acid vs. strong base neutralization reaction (ii) hydrogen bonding interaction between acetone and chloroform; Rates of the reaction between (i) sodium thiosulphate and hydrochloric acid, (ii) potassium iodate and sodium sulfite (iii) iodide vs. hydrogen peroxide, concentration and temperature effects in these reactions.
Purification Methods: Filtration, crystallization, sublimation, distillation, differential extraction, and chromatography. Principles of melting point and boiling point determination; principles of paper chromatographic separation – Rf values.
Qualitative Analysis of Organic Compounds: Detection of nitrogen, sulfur, phosphorous, and halogens; Detection of carbohydrates, fats, and proteins in foodstuff; Detection of alcoholic, phenolic, aldehydic, ketonic, carboxylic, amino groups, and unsaturation.
Quantitative Analysis of Organic Compounds: Basic principles for the quantitative estimation of carbon, hydrogen, nitrogen, halogen, sulfur, and phosphorous; Molecular mass determination by silver salt and chloroplatinate salt methods; Calculations of empirical and molecular formulae.
Principles of Organic Chemistry Experiments: Preparation of iodoform, acetanilide, p-nitro acetanilide, di-benzyl acetone, aniline yellow, beta-naphthol; Preparation of acetylene and study of its acidic character.
Basic Laboratory Technique: Cutting glass tube and glass rod, bending a glass tube, drawing out a glass jet, boring of cork.

Mathematics:

1. Algebra
Complex numbers, addition, multiplication, conjugation, polar representation, properties of modulus and principal argument, triangle inequality, roots of complex numbers, geometric interpretations; Fundamental theorem of algebra.
Theory of Quadratic equations, quadratic equations in real and complex number system and their solutions, the relation between roots and coefficients, nature of roots, equations reducible to quadratic equations.
Arithmetic, geometric and harmonic progressions, arithmetic, geometric and harmonic means, arithmetic and geometric series, sums of finite arithmetic and geometric progressions, infinite geometric series, sums of squares and cubes of the first n natural numbers.
Logarithms and their properties.
Exponential series.
Permutations and combinations, Permutations as an arrangement and combination as selection, simple applications.
Binomial theorem for a positive integral index, properties of binomial coefficients, Pascal’s triangle
Matrices and determinants of order two or three, properties and evaluation of determinants, addition and multiplication of matrices, adjoint and the inverse of matrices, Solutions of simultaneous linear equations in two or three variables, elementary row and column operations of matrices, types of matrices, applications of determinants in finding the area of triangles.
Sets, Relations and Functions, algebra of sets applications, equivalence relations, mappings, one-one, into and onto mappings, the composition of mappings, binary operation, the inverse of a function, functions of real variables like polynomial, modulus, signum, and greatest integer.
Mathematical reasoning and methods of proofs, Mathematically acceptable statements. Connecting words/phrases – consolidating the understanding of “ if and only if (necessary and sufficient) condition”, “implies”, “and/or”, “implied” by”, “and”, “our”, “ there exists” and through a variety of examples related to real life and Mathematics. Validating the statements involving the connecting words – the difference between contradiction, converse, and contrapositive., Mathematical induction
Linear Inequalities, solution of linear inequalities in one variable ( Algebraic) and two variables (Graphical).
2. Trigonometry
Measurement of angles in radians and degrees, positive and negative angles, trigonometric ratios, functions with their graphs and identities.
The solution of trigonometric equations.
Inverse trigonometric functions
3. Two-dimensional Coordinate Geometry
Cartesian coordinates, the distance between two points, section formulae, the shift of origin.
Straight lines and pair of straight lines: Equation of straight lines in various forms, the angle between two lines, the distance of a point from a line, lines through the point of intersection of two given lines, equation of the bisector of the angle between two lines, concurrent lines.
Circles: Equation of a circle in standard form, parametric equations of a circle.
Conic sections: parabola, ellipse, and hyperbola their eccentricity, directrices & foci.
4. Three-dimensional Coordinate Geometry
Co-ordinate axes and coordinate planes, the distance between two points, section formula, direction cosines and direction ratios, equation of a straight line in space, and skew lines.
The angle between two lines whose direction ratios are given, the shortest distance between two lines.
Equation of a plane, the distance of a point from a plane, condition for coplanarity of three lines, angles between two planes, the angle between a line and a plane.
5. Differential calculus
Domain and range of a real-valued function, Limits, and Continuity of the sum, difference, product, and quotient of two functions, Differentiability.
The derivative of different types of functions (polynomial, rational, trigonometric, inverse trigonometric, exponential, logarithmic, implicit functions), the derivative of the sum, difference, product, and quotient of two functions, chain rule, parametric form.
Geometric interpretation of derivatives, Tangents, and Normals.
Increasing and decreasing functions, Maxima and minima of a function.
Rolle’s Theorem, Mean Value Theorem, and Intermediate Value Theorem.
6. Integral calculus
Integration as the inverse process of differentiation, indefinite integrals of standard functions
Methods of integration: Integration by substitution, Integration by parts, integration by partial fractions, and integration by trigonometric identities.
Definite integrals and their properties, Fundamental Theorem of Integral Calculus, applications in finding areas under simple curves.
Application of definite integrals to the determination of areas of regions bounded by simple curves.
Integration as the inverse process of differentiation, indefinite integrals of standard functions
Methods of integration: Integration by substitution, Integration by parts, integration by partial fractions, and integration by trigonometric identities.
Definite integrals and their properties, Fundamental Theorem of Integral Calculus, applications in finding areas under simple curves.
Application of definite integrals to the determination of areas of regions bounded by simple curves.
7. Ordinary Differential Equations
Order and degree of a differential equation, formulation of a differential equation whole general solution is given, variables separable method.
The solution of homogeneous differential equations of the first order and first degree
Linear first-order differential equations
8. Probability
Various terminology in probability, axiomatic and other approaches of probability, addition and multiplication rules of probability.
Conditional probability, total probability, and Baye’s theorem
Independent events
Discrete random variables and distributions with mean and variance.
9. Vectors
Direction ratio/cosines of vectors, the addition of vectors, scalar multiplication, position vector of a point dividing a line segment in a given ratio.
Dot and cross products of two vectors, the projection of a vector on a line.
Scalar triple products and their geometrical interpretations.
10. Statistics
Measures of dispersion
Analysis of frequency distributions with equal means but different variances
11.Linear Programming
Various terminology and formulation of Linear Programming
The solution of linear Programming using graphical method, feasible and infeasible regions, feasible and infeasible solutions, optimal feasible solutions (up to three non-trivial constraints)

English Proficiency:

(a) English Proficiency: The paper is designed to test candidates proficiency in English and tests their basic grammar skills, vocabulary, reading skills, and how effective are they in English writing:

1. Grammar
The agreement, Time and Tense, Parallel construction, Relative pronouns
Determiners, Prepositions, Modals, Adjectives
Voice, Transformation
Question tags, Phrasal verbs
2. Vocabulary
Synonyms, Antonyms, Odd Word, One Word, Jumbled letters, Homophones, Spelling
Contextual meaning.
Analogy
3. Reading Comprehension
Content/ideas
Vocabulary
Referents
Idioms/Phrases
Reconstruction (rewording)
4. Composition
Rearrangement
Paragraph Unity
Linkers/Connectives

(b) Logical Reasoning – The test is conducted to test candidates’ reasoning power in verbal and nonverbal areas. The test checks a candidate’s logical level thinking and analyses how well they can think about it. Here we listed important topics which will be asked in the BITSAT Exam from the Logical reasoning section.

1. Verbal Reasoning
Analogy: Analogy means correspondence. In the questions based on analogy, a particular relationship is given and another similar relationship has to be identified from the alternatives provided.
Classification: Classification means to assort the items of a given group based on certain common qualities they possess and then spot the odd option out.
Series Completion: Here series of numbers or letters are given and one is asked to either complete the series or find out the wrong part in the series.
Logical Deduction – Reading Passage: Here a brief passage is given and based on the passage the candidate is required to identify the correct or incorrect logical conclusions.
Chart Logic: Here a chart or a table is given that is partially filled in and asks to complete it following the information given either in the chart/table or in the question.
2. Nonverbal Reasoning
Pattern Perception: Here a certain pattern is given and generally a quarter is left blank. The candidate is required to identify the correct quarter from the given four alternatives.
Figure Formation and Analysis: The candidate is required to analyze and form a figure from various given parts.
Paper Cutting: It involves the analysis of a pattern that is formed when a folded piece of paper is cut into a definite design.
Figure Matrix: In this, more than one set of figures is given in the form of a matrix, all of them following the same rule. The candidate is required to follow the rule and identify the missing figure.
Rule Detection: Here a particular rule is given and it is required to select from the given sets of figures, a set of figures, which obeys the rule and forms the correct series.

Biology:

1:  Diversity in Living World
Biology – it is meaning and relevance to mankind
What is living; Taxonomic categories and aids; Systematics and Binomial system of nomenclature.
Introductory classification of living organisms (Two-kingdom system, Five-kingdom system);
Plant kingdom – Salient features of major groups (Algae to Angiosperms);
Animal kingdom –Salient features of Nonchordates up to phylum, and Chordates up to class level.
2:  Cell: The Unit of Life; Structure and Function
Cell wall; Cell membrane; Endomembrane system (ER, Golgi apparatus/Dictyosome, Lysosomes, Vacuoles); Mitochondria; Plastids; Ribosomes; Cytoskeleton; Cilia and Flagella; Centrosome and Centriole; Nucleus; Microbodies.
Structural differences between prokaryotic and eukaryotic, and between plant and animal cells.
Cell cycle (various phases); Mitosis; Meiosis.
Biomolecules – Structure and function of Carbohydrates, Proteins, Lipids, and Nucleic acids.
Enzymes – Chemical nature, types, properties, and mechanism of action.
3:  Genetics and Evolution
Mendelian inheritance; Chromosome theory of inheritance; Gene interaction; Incomplete dominance; Co-dominance; Complementary genes; Multiple alleles;
Linkage and Crossing over; Inheritance patterns of hemophilia and blood groups in humans.
DNA –its organization and replication; Transcription and Translation;
Gene expression and regulation; DNA fingerprinting.
Theories and evidence of evolution, including modern Darwinism.
4:  Structure and Function – Plants
Morphology of a flowering plant; Tissues and tissue systems in plants; Anatomy and function of the root, stem (including modifications), leaf, inflorescence, flower (including position and arrangement of different whorls, placentation), fruit and seed; Types of fruit; Secondary growth;
Absorption and movement of water (including diffusion, osmosis, and water relations of the cell) and of nutrients; Translocation of food; Transpiration and gaseous exchange; Mechanism of stomatal movement.
Mineral nutrition – Macro- and micro-nutrients in plants including deficiency disorders; Biological nitrogen fixation mechanism.
Photosynthesis – Light reaction, cyclic and non-cyclic photophosphorylation; various pathways of carbon dioxide fixation; Photorespiration; Limiting factors.
Respiration – Anaerobic, Fermentation, Aerobic; Glycolysis, TCA cycle; Electron transport system; Energy relations.
5: Structure and Function  – Animals
Human Physiology – Digestive system – organs, digestion and absorption; Respiratory system – organs, breathing and exchange and transport of gases.
Body fluids and circulation – Blood, lymph, double circulation, regulation of cardiac activity; Hypertension, Coronary artery diseases.
Excretion system – Urine formation, regulation of kidney function
Locomotion and movement – Skeletal system, joints, muscles, types of movement.
Control and coordination – Central and peripheral nervous systems, structure and function of neuron, reflex action, and sensory reception; Role of various types of endocrine glands; Mechanism of hormone action.
6: Reproduction, Growth, and Movement in Plants
Asexual methods of reproduction;
Sexual Reproduction – Development of male and female gametophytes; Pollination (Types and agents); Fertilization; Development of embryo, endosperm, seed, and fruit (including parthenocarpy and helminth).
Growth and Movement – Growth phases; Types of growth regulators and their role in seed dormancy, germination, and movement;
Apical dominance; Senescence; Abscission; Photoperiodism; Vernalisation;
Various types of movements.
7Reproduction and Development in Humans
Male and female reproductive systems;
Menstrual cycle; Gamete production; Fertilization; Implantation;
Embryo development;
Pregnancy and parturition;
Birth control and contraception.
8:  Ecology and Environment
Meaning of ecology, environment, habitat, and niche.
Ecological levels of organization (organism to biosphere); Characteristics of Species, Population, Biotic Community and Ecosystem; Succession and Climax. Ecosystem – Biotic and abiotic components; Ecological pyramids; Food chain and Food web;
Energy flow; Major types of ecosystems including agroecosystem.
Ecological adaptations – Structural and physiological features in plants and animals of aquatic and desert habitats.
Biodiversity and Environmental Issues – Meaning, types, and conservation strategies (Biosphere reserves, National parks, and Sanctuaries), Air and Water Pollution (sources and major pollutants); Global warming and Climate change; Ozone depletion; Noise pollution; Radioactive pollution; Methods of pollution control (including an idea of bioremediation); Deforestation; Extinction of species (Hot Spots).
9:  Biology and Human Welfare
Animal husbandry – Livestock, Poultry, Fisheries; Major animal diseases and their control. Pathogens of major communicable diseases of humans are caused by fungi, bacteria, viruses, protozoans, and helminths, and their control.
Cancer; AIDS.
Adolescence and drug/alcohol abuse;
Basic concepts of immunology.
Plant Breeding and Tissue Culture in crop improvement.
10:  Biotechnology and its Applications
Microbes as an ideal system for biotechnology;
Microbial technology in food processing, industrial production (alcohol, acids, enzymes, antibiotics), sewage treatment, and energy generation.
Steps in recombinant DNA technology – restriction enzymes, NA insertion by vectors and other methods, regeneration of recombinants
Applications of R-DNA technology in human health –Production of Insulin, Vaccines and Growth hormones, Organ transplant, Gene therapy.
Applications in Industry and Agriculture – Production of expensive enzymes, strain improvement to scale up bioprocesses, GM crops by transfer of genes for nitrogen fixation, herbicide-resistance, and pest-resistance including Bt crops.

 

Preparation Tips for BITSAT 2024

Preparing for the BITSAT (Birla Institute of Technology and Science Admission Test) involves a methodical and focused approach. Here are 10 tips to help you get ready effectively for the BITSAT exam in 2024:

1. Understand the Exam Structure: Understand the BITSAT exam structure, including the number of questions, marking system, and time duration. This will help you plan your approach accordingly.

2. Create a Study Schedule: Build a well-organized study plan that covers all subjects and allows enough time for review. Distribute your time among Physics, Chemistry, Mathematics/Biology, and English/Logical Reasoning.

3. Check the Syllabus: Make sure you know the BITSAT syllabus. You must focus on the main topics and prioritize them based on your strengths and weaknesses. Spend more time on areas where you need improvement.

4. Regular Practice: Practice is vital for BITSAT success. Solve various sample papers, previous years’ question papers, and mock tests to enhance your time management skills and get used to the exam pattern.

5. Understand Concepts: Ensure a solid grasp of fundamental concepts. Clear any doubts and seek help from teachers, friends, or online resources to strengthen your understanding of important topics.

6. Manage Your Time: Develop effective time management skills. Practice solving questions within the given time to improve your speed and accuracy during the exam.

7. Focus on Weak Areas: Identify your weak areas and allocate extra time to improve them. This will help you address your vulnerabilities and perform better across all subjects.

8. Prioritize Revision: Review the topics you’ve covered regularly to reinforce your understanding. Create concise notes or flashcards to review important formulas and concepts quickly.

9. Stay Healthy: A healthy body and mind are crucial for optimal performance. Sleep well, maintain a balanced diet, and take short breaks during study sessions to stay focused and alert.

10. Mock Tests and Analysis: Regularly take full-length mock tests, preferably under exam-like conditions. Analyze your performance, identify mistakes, and work on improving them. This will help you assess your readiness and refine your strategy.

Remember, consistency and dedication are crucial for success. Stay focused, stay positive, and believe in your abilities. Best of luck with your BITSAT 2024 preparation!

Conclusion

As you can see, the BITSAT syllabus is vast. Therefore, you must follow a smart and effective strategy to cover it. Candidates must scan the syllabus thoroughly and jot down easy and difficult topics as per their understanding. After that, formulate an efficient timetable and follow it religiously.

Keep a track of time as time management is the key. Moreover, do not neglect taking mock tests and they help you prepare better.

Well, with this, we have reached the end of this article. We hope that the information provided above helps to clear out your doubts.

Prepare well and good luck!

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