List of Indian inventions and discoveries

This list of Indian inventions and discoveries details the inventions, scientific discoveries and contributions of India, including those from the historic Indian subcontinent and the modern-day republic of India. It draws from the whole cultural and technological history of India, during which architecture, astronomy, cartography, metallurgy, logic, mathematics, metrology and mineralogy were among the branches of study pursued by its scholars.[1] During recent times science and technology in the Republic of India has also focused on automobile engineering, information technology, communications as well as research into space and polar technology.

For the purpose of this list, the inventions are regarded as technological firsts developed within territory of India, as such does not include foreign technologies which India acquired through contact or any Indian origin living in foreign country doing any breakthroughs in foreign land. It also does not include not a new idea, indigenous alternatives, low-cost alternatives, technologies or discoveries developed elsewhere and later invented separately in India, nor inventions by Indian emigres or Indian diaspora in other places. Changes in minor concepts of design or style and artistic innovations do not appear in the lists.

Ancient India

edit

Agriculture

edit
  • Indigo dye – Indigo, a blue pigment and a dye, was used in India, which was also the earliest major centre for its production and processing.[2] The Indigofera tinctoria variety of Indigo was domesticated in India.[2] Indigo, used as a dye, made its way to the Greeks and the Romans via various trade routes, and was valued as a luxury product.[2]
  • Jute cultivation – Jute has been cultivated in India since ancient times.[3] Raw jute was exported to the western world, where it was used to make ropes and cordage.[3] The Indian jute industry, in turn, was modernised during the British Raj in India.[3] The region of Bengal was the major centre for Jute cultivation, and remained so before the modernisation of India's jute industry in 1855, when Kolkata became a centre for jute processing in India.[3]
  • Sugar – Sugarcane was originally from tropical South Asia and Southeast Asia,[4] with different species originating in India, and S. edule and S. officinarum from New Guinea.[4] The process of producing crystallised sugar from sugar cane, in India, dates to at least the beginning of the common era, with 1st century CE Greek and Roman authors writing on Indian sugar.[5][6] The process was soon transmitted to China with travelling Buddhist monks.[7] Chinese documents confirm at least two missions to India, initiated in 647 CE, for obtaining technology for sugar-refining.[8] Each mission returned with results on refining sugar.[8]

Construction, civil engineering and architecture

edit
 
The Great Stupa at Sanchi (4th–1st century BCE). The dome shaped stupa was used in India as a commemorative monument associated with storing sacred relics.
 
Hanuman and Ravana in Tolu Bommalata, the shadow puppet tradition of Andhra Pradesh, India
  • Stepwell – While the early history of stepwells is poorly understood, water structures in Western India were their likely predecessor.[9] The three features of stepwells in the subcontinent are evident from one particular site, abandoned by 2500 BCE, which combines a bathing pool, steps leading down to water, and figures of some religious importance into one structure.[9]
  • Stupa – The origin of the stupa can be traced to 3rd-century BCE India.[10] It was used as a commemorative monument associated with storing sacred relics.[10] The stupa architecture was adopted in Southeast and East Asia, where it evolved into the pagoda, a Buddhist monument used for enshrining sacred relics.[10]
  • Residential UniversityNalanda (Nālandā, pronounced [naːlən̪d̪aː]) was a renowned mahavihara (Buddhist monastic university) in ancient Magadha (modern-day Bihar), eastern India.[11][12][13] Considered by historians to be the world's first residential university[14] and among the greatest centres of learning in the ancient world, it was located near the city of Rajagriha (now Rajgir) and about 90 kilometres (56 mi) southeast of Pataliputra (now Patna) and operated from 427 until 1197 CE.[15]

Finance and banking

edit
  • Cheque/Check – There is early evidence of using cheques/checks. In India, during the Maurya Empire (from 321 to 185 BC), a commercial instrument called the "Adesha" was in use, which was an order on a banker desiring him to pay the money of the note to a third person (now known as or referred to as a "Negotiable Instrument").[16]

Games

edit
  • Atya-patya – This variation of tag was being played as early as 100 CE, and was possibly invented by farmers as a way of practicing driving away birds. It was later used as a form of military training in Kerala in close relation to the martial art of kalaripayattu.[17]
  • Badminton – The game may have originally developed among expatriate officers in British India[18][19]
  • Blindfold chessGames prohibited by Buddha includes a variant of ashtapada game played on imaginary boards. Akasam astapadam was an ashtapada variant played with no board, literally "astapadam played in the sky". A correspondent in the American Chess Bulletin identifies this as likely the earliest literary mention of a blindfold chess variant.[20]
  • Carrom – The game of carrom originated in India.[21] One carrom board with its surface made of glass is still available in one of the palaces in Patiala, India.[22] It became very popular among the masses after World War I. State-level competitions were being held in the different states of India during the early part of the twentieth century. Serious carrom tournaments may have begun in Sri Lanka in 1935 but by 1958, both India and Sri Lanka had formed official federations of carrom clubs, sponsoring tournaments and awarding prizes.[23]
  • Chaturanga – The precursor of chess originated in India during the Gupta dynasty (c. 280–550 CE).[24][25][26][27] Both the Persians and Arabs ascribe the origins of the game of Chess to the Indians.[26][28][29] The words for "chess" in Old Persian and Arabic are chatrang and shatranj respectively – terms derived from caturaṅga in Sanskrit,[30][31] which literally means an army of four divisions or four corps.[32][33] Chess spread throughout the world and many variants of the game soon began taking shape.[34] This game was introduced to the Near East from India and became a part of the princely or courtly education of Persian nobility.[32] Buddhist pilgrims, Silk Road traders and others carried it to the Far East where it was transformed and assimilated into a game often played on the intersection of the lines of the board rather than within the squares.[34] Chaturanga reached Europe through Persia, the Byzantine empire and the expanding Arabian empire.[33][35] Muslims carried Shatranj to North Africa, Sicily, and Spain by the 10th century where it took its final modern form of chess.[34]
  • Kabaddi – The game of kabaddi originated in India during prehistory.[36] Suggestions on how it evolved into the modern form range from wrestling exercises, military drills, and collective self-defence but most authorities agree that the game existed in some form or the other in India during the period between 1500 and 400 BCE.[36]
  • Kalaripayattu – One of the world's oldest form of martial arts is Kalaripayattu that developed in the southwest state of Kerala in India.[37] It is believed to be the oldest surviving martial art in India, with a history spanning over 3,000 years.[38]
  • Kho-kho – This is one of the oldest variations of tag in the world, having been played since as early as the fourth century BCE.[39]
  • LudoPachisi originated in India by the 6th century.[40] The earliest evidence of this game in India is the depiction of boards on the caves of Ajanta.[40] A variant of this game, called Ludo, made its way to England during the British Raj.[40]
  • Mallakhamba – It is a traditional sport, originating from the Indian subcontinent, in which a gymnast performs aerial yoga or gymnastic postures and wrestling grips in concert with a vertical stationary or hanging wooden pole, cane, or rope.The earliest literary known mention of Mallakhamb is in the 1135 CE Sanskrit classic Manasollasa, written by Someshvara III. It has been thought to be the ancestor of Pole Dancing.
  • Nuntaa, also known as Kutkute.[41]
  • Seven stones – An Indian subcontinent game also called Pitthu is played in rural areas has its origins in the Indus Valley Civilization.[42]
  • Snakes and ladders – Vaikunta pali Snakes and ladders originated in India as a game based on morality.[43] During British rule of India, this game made its way to England, and was eventually introduced in the United States of America by game-pioneer Milton Bradley in 1943.[43]
  • Suits game: Kridapatram is an early suits game, made of painted rags, invented in Ancient India. The term kridapatram literally means "painted rags for playing."[44][45][46][47][48] Paper playing cards first appeared in East Asia during the 9th century.[44][49] The medieval Indian game of ganjifa, or playing cards, is first recorded in the 16th century.[50]
  • Table tennis – It has been suggested that makeshift versions of the game were developed by British military officers in India around the 1860s or 1870s, who brought it back with them.[51]
  • Vajra-mushti – refers to a wrestling where knuckleduster like weapon is employed.The first literary mention of vajra-musti comes from the Manasollasa of the Chalukya king Someswara III (1124–1138), although it has been conjectured to have existed since as early as the Maurya dynasty[52][53]

Textile and material production

edit
  • Button – Ornamental buttons—made from seashell—were used in the Indus Valley civilization for ornamental purposes by 2000 BCE.[54] Some buttons were carved into geometric shapes and had holes pierced into them so that they could be attached to clothing by using a thread.[54] Ian McNeil (1990) holds that: "The button, in fact, was originally used more as an ornament than as a fastening, the earliest known being found at Mohenjo-daro in the Indus Valley. It is made of a curved shell and about 5000 years old."[55]
 
A Nepali Charkha in action
  • Calico – Calico had originated in the subcontinent by the 11th century and found mention in Indian literature, by the 12th-century writer Hemachandra. He has mentioned calico fabric prints done in a lotus design.[56] The Indian textile merchants traded in calico with the Africans by the 15th century and calico fabrics from Gujarat appeared in Egypt.[56] Trade with Europe followed from the 17th century onward.[56] Within India, calico originated in Kozhikode.[56]
  • Carding devices – Historian of science Joseph Needham ascribes the invention of bow-instruments used in textile technology to India.[57] The earliest evidence for using bow-instruments for carding comes from India (2nd century CE).[57] These carding devices, called kaman and dhunaki would loosen the texture of the fibre by the means of a vibrating string.[57]
  • Cashmere – The fibre cashmere fibre also known as pashm or pashmina for its use in the handmade shawls of Kashmir, India.[58] The woolen shawls made from wool in Indian administered Kashmir find written mention between the 3rd century BCE and the 11th century CE.[59]
  • Charkha (Spinning wheel): invented in India, between 500 and 1000 CE.[60]
  • Chintz – The origin of Chintz is from the printed all cotton fabric of calico in India.[61] The origin of the word chintz itself is from the Hindi language word चित्र् (chitr), which means an image.[61][62]
  • Cotton cultivation – Cotton was cultivated by the inhabitants of the Indus Valley civilisation by the 5th millennium BCE – 4th millennium BCE.[63] The Indus cotton industry was well developed and some methods used in cotton spinning and fabrication continued to be practised until the modern industrialisation of India.[64] Well before the Common Era, the use of cotton textiles had spread from India to the Mediterranean and beyond.[65]
  • Single roller cotton gin – The Ajanta Caves of India yield evidence of a single roller cotton gin in use by the 5th century.[66] This cotton gin was used in India until innovations were made in form of foot powered gins.[67] The cotton gin was invented in India as a mechanical device known as charkhi, more technically the "wooden-worm-worked roller". This mechanical device was, in some parts of India, driven by water power.[57]
  • Worm drive cotton gin – The worm drive later appeared in the Indian subcontinent, for use in roller cotton gins, during the Delhi Sultanate in the thirteenth or fourteenth centuries.[68]
  • Crank Handle Cotton Gin – The incorporation of the crank handle in the cotton gin, first appeared in either the late Delhi Sultanate or the early Mughal Empire.[69]
  • Palamporeपालमपोर् (Hindi language) of Indian origin[70] was imported to the western world—notable England and Colonial America—from India.[71][72] In 17th-century England these hand painted cotton fabrics influenced native crewel work design.[71] Shipping vessels from India also took palampore to colonial America, where it was used in quilting.[72]
  • Prayer flags – The Buddhist sūtras, written on cloth in India, were transmitted to other regions of the world.[73] These sutras, written on banners, were the origin of prayer flags.[73] Legend ascribes the origin of the prayer flag to the Shakyamuni Buddha, whose prayers were written on battle flags used by the devas against their adversaries, the asuras.[74] The legend may have given the Indian bhikku a reason for carrying the 'heavenly' banner as a way of signyfying his commitment to ahimsa.[75] This knowledge was carried into Tibet by 800 CE, and the actual flags were introduced no later than 1040 CE, where they were further modified.[75] The Indian monk Atisha (980–1054 CE) introduced the Indian practice of printing on cloth prayer flags to Tibet.[74]
  • Tanning (leather) – Ancient civilizations used leather for waterskins, bags, harnesses and tack, boats, armour, quivers, scabbards, boots, and sandals. Tanning was being carried out by the inhabitants of Mehrgarh in Ancient India between 7000 and 3300 BCE.[76]
  • Roller sugar mill – Geared sugar rolling mills first appeared in Mughal India, using the principle of rollers as well as worm gearing, by the 17th century.[77]

Well-being

edit
  • Indian clubs: The Indian club—which appeared in Europe during the 18th century—was used long by India's native soldiery before its introduction to Europe.[78] During the British Raj the British officers in India performed calisthenic exercises with clubs to keep in physical condition.[78] From Britain the use of club swinging spread to the rest of the world.[78]
  • Shampoo – The word shampoo in English is derived from Hindustani cā̃po (चाँपो IPA: [tʃãːpoː]),[79] and dates to 1762.[80] A variety of herbs and their extracts were used as shampoos since ancient times in India, evidence of early herbal shampoo have been discovered from Indus Valley Civilization site of Banawali dated to 2750–2500 BCE.[81] A very effective early shampoo was made by boiling Sapindus with dried Indian gooseberry (aamla) and a few other herbs, using the strained extract. Sapindus, also known as soapberries or soapnuts, is called Ksuna (Sanskrit: क्षुण)[82] in ancient Indian texts and its fruit pulp contain saponins, a natural surfactant. The extract of Ksuna, creates a lather which Indian texts identify as phenaka (Sanskrit: फेनक),[83] leaves the hair soft, shiny and manageable. Other products used for hair cleansing were shikakai (Acacia concinna), soapnuts (Sapindus), hibiscus flowers,[84][85] ritha (Sapindus mukorossi) and arappu (Albizzia amara).[86] Guru Nanak, the founding prophet and the first Guru of Sikhism, made references to soapberry tree and soap in 16th century.[87] Washing of hair and body massage (champu) during a daily strip wash was an indulgence of early colonial traders in India. When they returned to Europe, they introduced their newly learnt habits, including the hair treatment they called shampoo.[88]
  • Yoga – Yoga as a physical, mental, and spiritual practice originated in ancient India.[89]

Medicine

edit
 
A statue of Sushruta (600 BCE), author of Sushruta Samhita and the founding father of surgery, at Royal Australasian College of Surgeons (RACS) in Melbourne, Australia
  • Angina pectoris – The condition was named "hritshoola" in ancient India and was described by Sushruta (6th century BCE).[90]
  • Ayurvedic and Siddha medicine – Ayurveda and Siddha are ancient systems of medicine practised in South Asia. Ayurvedic ideas can be found in the Hindu text[91] (mid-first millennium BCE). Ayurveda has evolved over thousands of years, and is still practised today. In an internationalised form, it can be thought of as a complementary and alternative medicine. In village settings, away from urban centres, it is simply "medicine." The Sanskrit word आयुर्वेदः (āyur-vedaḥ) means "knowledge (veda) for longevity (āyur)".[92] Siddha medicine is mostly prevalent in South India, and is transmitted in Tamil, not Sanskrit, texts. Herbs and minerals are basic raw materials of the Siddha therapeutic system whose origins may be dated to the early centuries CE.[93][94]
  • Leprosy: Kearns & Nash (2008) state that the first mention of leprosy is described in the Indian medical treatise Sushruta Samhita (6th century BCE).[95] However, The Oxford Illustrated Companion to Medicine holds that the mention of leprosy, as well as ritualistic cures for it, were described in the Atharva-veda (1500–1200 BCE), written before the Sushruta Samhita.[96]
  • Lithiasis treatment – The earliest operation for treating lithiasis, or the formations of stones in the body, is also given in the Sushruta Samhita (6th century BCE).[97] The operation involved exposure and going up through the floor of the bladder.[97]
  • Visceral leishmaniasis, treatment of – The Indian (Bengali) medical practitioner Upendranath Brahmachari (19 December 1873 – 6 February 1946) was nominated for the Nobel Prize in Physiology or Medicine in 1929 for his discovery of 'ureastibamine (antimonial compound for treatment of kala azar) and a new disease, post-kalaazar dermal leishmanoid.'[98] Brahmachari's cure for Visceral leishmaniasis was the urea salt of para-amino-phenyl stibnic acid which he called Urea Stibamine.[99] Following the discovery of Urea Stibamine, Visceral leishmaniasis was largely eradicated from the world, except for some underdeveloped regions.[99]
  • Ganja was used as herb for ayurverdic medicine development for last 2,000 years. The Sushruta Samhita, an ancient medical treatise, recommends cannabis plant extract for treating respiratory ailments and diarrhoea.
  • Otoplasty – Ear surgery was developed in ancient India and is described in the medical compendium, the Sushruta Samhita (Sushruta's Compendium, c. 500 AD). The book discussed otoplastic and other plastic surgery techniques and procedures for correcting, repairing and reconstructing ears, noses, lips, and genitalia that were amputated as criminal, religious, and military punishments. The ancient Indian medical knowledge and plastic surgery techniques of the Sushruta Samhita were practiced throughout Asia until the late 18th century; the October 1794 issue of the contemporary British Gentleman's Magazine reported the practice of rhinoplasty, as described in the Sushruta Samhita. Moreover, two centuries later, contemporary practices of otoplastic praxis were derived from the techniques and procedures developed and established in antiquity by Sushruta.[100][101]
  • Tonsillectomy – Tonsillectomies have been practiced for over 2,000 years, with varying popularity over the centuries.[102] The earliest mention of the procedure is in "Hindu medicine" from about 1000 BCE
  • Caesarian section – The Sanskrit medical treatise Sushruta Samhita, composed in the early 1st millennium CE, mentions post-mortem caesarean sections.[103] The first available non-mythical record of a C-section is the mother of Bindusara (born c. 320 BC, ruled 298 – c. 272 BC), the second Mauryan Samrat (emperor) of India, accidentally consumed poison and died when she was close to delivering him. Chanakya, Chandragupta's teacher and adviser, made up his mind that the baby should survive. He cut open the belly of the queen and took out the baby, thus saving the baby's life.[104]

Equestrianism

edit
  • Toe stirrup – The earliest known manifestation of the stirrup, which was a toe loop that held the big toe was used in India in as early as 500 BCE[105] or perhaps by 200 BCE according to other sources.[106][107] This ancient stirrup consisted of a looped rope for the big toe which was at the bottom of a saddle made of fibre or leather.[107] Such a configuration made it suitable for the warm climate of most of India where people used to ride horses barefoot.[107] A pair of megalithic double bent iron bars with curvature at each end, excavated in Junapani in the central Indian state of Madhya Pradesh have been regarded as stirrups although they could as well be something else.[108] Buddhist carvings in the temples of Sanchi, Mathura and the Bhaja caves dating back between the 1st and 2nd century BCE figure horsemen riding with elaborate saddles with feet slipped under girths.[109][110][111] Sir John Marshall described the Sanchi relief as "the earliest example by some five centuries of the use of stirrups in any part of the world".[111] In the 1st century CE horse riders in northern India, where winters are sometimes long and cold, were recorded to have their booted feet attached to hooked stirrups.[106] However the form, the conception of the primitive Indian stirrup spread west and east, gradually evolving into the stirrup of today.[107][110]

Metallurgy, gems and other commodities

edit
  • Iron working – Iron works were developed in India, around the same time as, but independently of, Anatolia and the Caucasus. Archaeological sites in India, such as Malhar, Dadupur, Raja Nala Ka Tila and Lahuradewa in present-day Uttar Pradesh show iron implements in the period between 1800 BCE—1200 BCE.[112] Early iron objects found in India can be dated to 1400 BCE by employing the method of radiocarbon dating. Spikes, knives, daggers, arrow-heads, bowls, spoons, saucepans, axes, chisels, tongs, door fittings etc. ranging from 600 BCE to 200 BCE have been discovered from several archaeological sites of India.[113] Some scholars believe that by the early 13th century BCE, iron smelting was practised on a bigger scale in India, suggesting that the date the technology's inception may be placed earlier.[112] In Southern India (present day Mysore) iron appeared as early as 11th to 12th centuries BCE; these developments were too early for any significant close contact with the northwest of the country.[114] In the time of Chandragupta II Vikramaditya (375–413 CE), corrosion-resistant iron was used to erect the Iron pillar of Delhi, which has withstood corrosion for over 1,600 years.[115]
  • Crucible steel – Perhaps as early as 300 BCE—although certainly by 200 BCE—high quality steel was being produced in southern India, by what Europeans would later call the crucible technique.[116] In this system, high-purity wrought iron, charcoal, and glass were mixed in a crucible and heated until the iron melted and absorbed the carbon.[116]
  • Dockyard – The world's earliest enclosed dockyard was built in the Harappan port city of Lothal circa 2600 BC in Gujarat, India.[117][118]
  • Diamond drills – in the 12th century BCE or 7th century BCE, Indians not only innovated use of diamond tipped drills but also invented double diamond tipped drills for bead manufacturing.[119]
  • Diamond cutting and polishing – The technology of cutting and polishing diamonds was invented in India, Ratnapariksha, a text dated to 6th century talks about diamond cutting and Al-Beruni speaks about the method of using lead plate for diamond polishing in the 11th century CE.[120]
  • Draw bar – The draw bar was applied to sugar-milling, with evidence of its use at Delhi in the Mughal Empire by 1540, but possibly dating back several centuries earlier to the Delhi Sultanate.[121]
  • Etched carnelian beads – are a type of ancient decorative beads made from carnelian with an etched design in white. They were made according to a technique of alkaline-etching developed by the Harappans during the 3rd millennium BCE and were widely disperced from China in the east to Greece in the west.[122][123][124]
  • Glassblowing – Rudimentary form of glass blowing from Indian subcontinent is attested earlier than Western Asian counterparts(where it is attested not earlier than 1st century BCE) in the form of Indo-Pacific beads which uses glass blowing to make cavity before being subjected to tube drawn technique for bead making dated more than 2500 BP.[125][126] Beads are made by attaching molten glass gather to the end of a blowpipe, a bubble is then blown into the gather.[127] The glass blown vessels were rarely attested and were imported commodity in 1st millennium CE though.
  • Lost-wax casting – Metal casting by the Indus Valley civilization began around 3500 BC in the Mohenjodaro area,[128] which produced one of the earliest known examples of lost-wax casting, an Indian bronze figurine named the "dancing girl" that dates back nearly 5,000 years to the Harappan period (c. 3300–1300 BC).[128][129] Other examples include the buffalo, bull and dog found at Mohenjodaro and Harappa,[130][129][131] two copper figures found at the Harappan site Lothal in the district of Ahmedabad of Gujarat,[128] and likely a covered cart with wheels missing and a complete cart with a driver found at Chanhudaro.[130][131]
  • Seamless celestial globe – Considered one of the most remarkable feats in metallurgy, it was invented in India in between 1589 and 1590 CE.[132][133] Before they were rediscovered in the 1980s, it was believed by modern metallurgists to be technically impossible to produce metal globes without any seams, even with modern technology.[133]
  • Stoneware – Earliest stonewares, predecessors of porcelain have been recorded at Indus Valley Civilization sites of Harappa and Mohenjo Daro, they were used for making stoneware bangles.[134][135][136]
  • Tube drawn technology: Indians used tube drawn technology for glass bead manufacturing which was first developed in the 2nd century BCE.[137][138][127]
  • Tumble polishing – Indians innvoted polishing method in the 10th century BCE for mass production of polished stone beads.[139][119][140][141]
  • Wootz steel – Wootz steel is an ultra-high carbon steel and the first form of crucible steel manufactured by the applications and use of nanomaterials in its microstructure and is characterised by its ultra-high carbon content exhibiting properties such as superplasticity and high impact hardness.[142] Archaeological and Tamil language literary evidence suggests that this manufacturing process was already in existence in South India well before the common era, with wootz steel exported from the Chera dynasty and called Seric Iron in Rome, and later known as Damascus steel in Europe.[143][144][145][146] Reproduction research is undertaken by scientists Dr. Oleg Sherby and Dr. Jeff Wadsworth and the Lawrence Livermore National Laboratory have all attempted to create steels with characteristics similar to Wootz, but without success. J.D Verhoeven and Al Pendray attained some success in the reconstruction methods of production, proved the role of impurities of ore in the pattern creation, and reproduced Wootz steel with patterns microscopically and visually identical to one of the ancient blade patterns.[147]
  • Rain gauge – People living in India began to record rainfall in 400 BCE.[148] The readings were correlated against expected growth. In the Arthashastra, used for example in Magadha, precise standards were set as to grain production. Each state storehouse was equipped with a rain gauge to classify land for taxation purposes.[149]
  • Touchstone – The touchstone was used during the Harappa period of the Indus Valley civilization ca. 2600–1900 BC for testing the purity of soft metals.[150]

Metrology

edit
  • Standardisation – The oldest applications and evidence of standardisation come from the Indus Valley Civilisation in the 5th millennium BCE characterised by the existence of weights in various standards and categories as[151] well as the Indus merchants usage of a centralised weight and measure system. Small weights were used to measure luxury goods, and larger weights were used for buying bulkier items, such as food grains etc.[151] The weights and measures of the Indus civilisation also reached Persia and Central Asia, where they were further modified.[152]

A total of 558 weights were excavated from Mohenjodaro, Harappa, and Chanhu-daro, not including defective weights. They did not find statistically significant differences between weights that were excavated from five different layers, each about 1.5 m in thickness. This was evidence that strong control existed for at least a 500-year period. The 13.7-g weight seems to be one of the units used in the Indus valley. The notation was based on the binary and decimal systems. 83% of the weights which were excavated from the above three cities were cubic, and 68% were made of chert.[153]

Weapons

edit

Philosophy and logic

edit
  • Catuskoti (Tetralemma) – The four-cornered system of logical argumentation with a suite of four distinct functions that refers to a logical proposition P, with four possibilities that can arise. The tetralemma has many logico-epistemological applications and has been made ample use of by the Indian philosopher Nāgarjuna in the Madhyamaka school. The tetralemma also features prominently in the Greek skepticist school of Pyrrhonism, the teachings of which are based on Buddhism. According to Christopher I. Beckwith ,the founder of the Pyrrhonist school lived in India for 18 months and likely learned the language, which allowed him to carry these teachings to Greece.[159] However, other scholars, such as Stephen Batchelor[160] and Charles Goodman[161] question Beckwith's conclusions about the degree of Buddhist influence on Pyrrho
  • Trairūpya – Trairūpya is a logical argument that contains three constituents which a logical ‘sign’ or ‘mark’ (linga) must fulfill to be 'valid source of knowledge' (pramana):
  1. It should be present in the case or object under consideration, the ‘subject-locus' (pakṣa)
  2. It should be present in a ‘similar case’ or a homologue (sapakṣa)
  3. It should not be present in any ‘dissimilar case’ or heterologue (vipakṣa)
When a ‘sign’ or ‘mark’ (linga) is identified, there are three possibilities: the sign may be present in all, some, or none of the sapakṣas. Likewise, the sign may be present in all, some or none of the vipakṣas. To identify a sign, we have to assume that it is present in the pakṣa, however; that is the first condition is already satisfied. Combining these, Dignaga constructed his ‘Wheel of Reason’ (Sanskrit: Hetucakra).[162]
The seven predicate theory consists in the use of seven claims about sentences, each preceded by "arguably" or "conditionally" (syat), concerning a single object and its particular properties, composed of assertions and denials, either simultaneously or successively, and without contradiction. These seven claims are the following.
  1. Arguably, it (that is, some object) exists (syad asty eva).
  2. Arguably, it does not exist (syan nasty eva).
  3. Arguably, it exists; arguably, it doesn't exist (syad asty eva syan nasty eva).
  4. Arguably, it is non-assertible (syad avaktavyam eva).
  5. Arguably, it exists; arguably, it is non-assertible (syad asty eva syad avaktavyam eva).
  6. Arguably, it doesn't exist; arguably, it is non-assertible (syan nasty eva syad avaktavyam eva).
  7. Arguably, it exists; arguably, it doesn't exist; arguably it is non-assertible (syad asty eva syan nasty eva syad avaktavyam eva).

Mathematics

edit
Number System Numbers
0 1 2 3 4 5 6 7 8 9
Tamil
Gurmukhi o
Odia
Bengali
Assamese
Devanagari
Gujarati
Tibetan
Telugu
Kannada
Malayalam
Burmese
Khmer
Thai
Lao
Balinese
Santali
Javanese
 
The half-chord version of the sine function was developed by the Indian mathematician Aryabhatta.
 
Brahmagupta's theorem (598–668) states that AF = FD.
  • Zero – Zero and its operation are first defined by (Hindu astronomer and mathematician) Brahmagupta in 628.[164] The Babylonians used a space, and later a zero glyph, in their written Sexagesimal system, to signify the 'absent',[165] the Olmecs used a positional zero glyph in their Vigesimal system, the Greeks, from Ptolemy's Almagest, in a Sexagesimal system. The Chinese used a blank, in the written form of their decimal Counting rods system. A dot, rather than a blank, was first seen to denote zero, in a decimal system, in the Bakhshali manuscript.[166] The usage of the zero in the Bakhshali manuscript was dated from between 3rd and 4th centuries, making it the earliest known usage of a written zero, in a decimal place value system.[167]
  • Hindu number system – With decimal place-value and a symbol for zero, this system was the ancestor of the widely used Arabic numeral system. It was developed in the Indian subcontinent between the 1st and 6th centuries CE.[168][169]
  • Law of signs in multiplication – The earliest use of notation for negative numbers, as subtrahend, is credited by scholars to the Chinese, dating back to the 2nd century BCE.[170] Like the Chinese, the Indians used negative numbers as subtrahend, but were the first to establish the "law of signs" with regards to the multiplication of positive and negative numbers, which did not appear in Chinese texts until 1299.[170] Indian mathematicians were aware of negative numbers by the 7th century,[170] and their role in mathematical problems of debt was understood.[171] Mostly consistent and correct rules for working with negative numbers were formulated,[172] and the diffusion of these rules led the Arab intermediaries to pass it on to Europe.,[171] for example (+)×(-)=(-),(-)×(-)=(+) etc.
  • Sign convention – Symbols, signs and mathematical notation were employed in an early form in India by the 6th century when the mathematician-astronomer Aryabhata recommended the use of letters to represent unknown quantities.[173] By the 7th century Brahmagupta had already begun using abbreviations for unknowns, even for multiple unknowns occurring in one complex problem.[173] Brahmagupta also managed to use abbreviations for square roots and cube roots.[173] By the 7th century fractions were written in a manner similar to the modern times, except for the bar separating the numerator and the denominator.[173] A dot symbol for negative numbers was also employed.[173] The Bakhshali Manuscript displays a cross, much like the modern '+' sign, except that it symbolised subtraction when written just after the number affected.[173] The '=' sign for equality did not exist.[173] Indian mathematics was transmitted to the Islamic world where this notation was seldom accepted initially and the scribes continued to write mathematics in full and without symbols.[174]
  • Modern elementary arithmetic – Modum indorum or the method of the Indians for arithmetic operations was popularised by Al-Khwarizmi and Al-Kindi by means of their respective works such as in Al-Khwarizmi's on the Calculation with Hindu Numerals (ca. 825), On the Use of the Indian Numerals (ca. 830)[175] as early as the 8th and 9th centuries.They, amongst other works, contributed to the diffusion of the Indian system of arithmetic in the Middle-East and the West.The significance of the development of the positional number system is described by the French mathematician Pierre Simon Laplace (1749–1827) who wrote:

"It is India that gave us the ingenuous method of expressing all numbers by the means of ten symbols, each symbol receiving a value of position, as well as an absolute value; a profound and important idea which appears so simple to us now that we ignore its true merit, but its very simplicity, the great ease which it has lent to all computations, puts our arithmetic in the first rank of useful inventions, and we shall appreciate the grandeur of this achievement when we remember that it escaped the genius of Archimedes and Apollonius, two of the greatest minds produced by antiquity."

  • Chakravala method – The Chakravala method, a cyclic algorithm to solve indeterminate quadratic equations is commonly attributed to Bhāskara II, (c. 1114 – 1185 CE)[176][177][178] although some attribute it to Jayadeva (c. 950~1000 CE).[179] Jayadeva pointed out that Brahmagupta's approach to solving equations of this type would yield infinitely large number of solutions, to which he then described a general method of solving such equations.[180] Jayadeva's method was later refined by Bhāskara II in his Bijaganita treatise to be known as the Chakravala method, chakra (derived from cakraṃ चक्रं) meaning 'wheel' in Sanskrit, relevant to the cyclic nature of the algorithm.[180][181] With reference to the Chakravala method, E. O. Selenuis held that no European performances at the time of Bhāskara, nor much later, came up to its marvellous height of mathematical complexity.[176][180][182]
  • Trigonometric functions – The trigonometric functions sine and versine originated in Indian astronomy along with the cosine and inversine , adapted from the full-chord Greek versions (to the modern half-chord versions). They were described in detail by Aryabhata in the late 5th century, but were likely developed earlier in the Siddhantas, astronomical treatises of the 3rd or 4th century.[183][184] Later, the 6th-century astronomer Varahamihira discovered a few basic trigonometric formulas and identities, such as sin^2(x) + cos^2(x) = 1.[185]
  • Mean value theorem – A special case of this theorem for inverse interpolation of the sine was first described by Parameshvara (1380–1460), from the Kerala School of Astronomy and Mathematics in India, in his commentaries on Govindasvāmi and Bhāskara II.[186]
  • Bhāskara I's sine approximation formula
  • Madhava series – The infinite series for π and for the trigonometric sine, cosine, and arctangent is now attributed to Madhava of Sangamagrama (c. 1340 – 1425) and his Kerala school of astronomy and mathematics.[187][188] He made use of the series expansion of   to obtain an infinite series expression for π.[187] Their rational approximation of the error for the finite sum of their series are of particular interest. They manipulated the error term to derive a faster converging series for π.[189] They used the improved series to derive a rational expression,[189]  for π correct up to eleven decimal places, i.e.  .[190][191] Madhava of Sangamagrama and his successors at the Kerala school of astronomy and mathematics used geometric methods to derive large sum approximations for sine, cosine, and arctangent. They found a number of special cases of series later derived by Brook Taylor series. They also found the second-order Taylor approximations for these functions, and the third-order Taylor approximation for sine.[192][193][194]
  • Power series – The Kerala school of astronomy and mathematics or the Kerala school was a school of mathematics and astronomy founded by Madhava of Sangamagrama in Tirur, Malappuram, Kerala, India. Their work, completed two centuries before the invention of calculus in Europe, provided what is now considered the first example of a power series (apart from geometric series). However, they did not formulate a systematic theory of differentiation and integration.[195]
  • Finite difference interpolation – The Indian mathematician Brahmagupta presented what is possibly the first instance[196][197] of finite difference interpolation around 665 CE.[198]
  • Algebraic abbreviations – The mathematician Brahmagupta had begun using abbreviations for unknowns by the 7th century.[173] He employed abbreviations for multiple unknowns occurring in one complex problem.[173] Brahmagupta also used abbreviations for square roots and cube roots.[173]
  • Systematic generation of all permutations – The method goes back to Narayana Pandita in 14th century India, and has been rediscovered frequently.[199]
  • Discovered by the Indian mathematician, Brahmagupta (598–668 CE):[200][201][202][203]
  • Combinatorics – the Bhagavati Sutra had the first mention of a combinatorics problem; the problem asked how many possible combinations of tastes were possible from selecting tastes in ones, twos, threes, etc. from a selection of six different tastes (sweet, pungent, astringent, sour, salt, and bitter). The Bhagavati is also the first text to mention the choose function.[204] In the second century BC, Pingala included an enumeration problem in the Chanda Sutra (also Chandahsutra) which asked how many ways a six-syllable metre could be made from short and long notes.[205][206] Pingala found the number of metres that had   long notes and   short notes; this is equivalent to finding the binomial coefficients.
  • Jain texts define five different types of infinity – the infinite in one direction, the infinite in two directions, the infinite in area, the infinite everywhere, and the infinite perpetually.[207] and the Satkhandagama
  • Fibonacci numbers – This sequence was first described by Virahanka (c. 700 CE), Gopāla (c. 1135), and Hemachandra (c. 1150),[208] as an outgrowth of the earlier writings on Sanskrit prosody by Pingala (c. 200 BCE).
  • Madhava's correction terms – Madhava's correction term is a mathematical expression attributed to Madhava of Sangamagrama (c. 1340 – c. 1425), the founder of the Kerala school of astronomy and mathematics, that can be used to give a better approximation to the value of the mathematical constant π (pi) than the partial sum approximation obtained by truncating the Madhava-Leibniz infinite series for π. The Madhava-Leibniz infinite series for π.
  • Pascal's triangle – Described in the 6th century CE by Varahamihira[185] and in the 10th century by Halayudha,[209] commenting on an obscure reference by Pingala (the author of an earlier work on prosody) to the "Meru-prastaara", or the "Staircase of Mount Meru", in relation to binomial coefficients. (It was also independently discovered in the 10th or 11th century in Persia and China.)
  • Integral solution to Pell's equation – About a thousand years before Pell's time, Indian scholar Brahmagupta (598–668 CE) was able to find integral solutions to vargaprakṛiti (Pell's equation):[210][211]   where N is a non-square integer, in his Brâhma-sphuṭa-siddhânta treatise.[212]
  • Ardhacheda – Earlier than Michael Stifel, the 8th century Jain mathematician Virasena is credited with a precursor to the binary logarithm. Virasena's concept of ardhacheda has been defined as the number of times a given number can be divided evenly by two. This definition gives rise to a function that coincides with the binary logarithm on the powers of two,[213] but it is different for other integers, giving the 2-adic order rather than the logarithm.[214]
  • Kuṭṭaka – The Kuṭṭaka algorithm has much similarity with and can be considered as a precursor of the modern day extended Euclidean algorithm. The latter algorithm is a procedure for finding integers x and y satisfying the condition ax + by = gcd(a, b).[215]
  • Preliminary differentiation – Preliminary concept of differentiation and the differential coefficient were known to bhaskaracharya[216]

Linguistics and Literature

edit

"[That army], which relished battle (rasāhavā) contained allies who brought low the bodes and gaits of their various striving enemies (sakāranānārakāsakāyasādadasāyakā), and in it the cries of the best of mounts contended with musical instruments (vāhasāranādavādadavādanā)."

Palindromic Novel: The Ramakrishna Vilomakavyam by Dyvagnya Surya Pandita is an example of a narrative that, when read forward, relate the story of the Ramayana and, when read backward, relate the story of the Mahabharata.

Mining

edit
  • Diamond mining and diamond tools: Diamonds were first recognised and mined in central India,[219][220][221] where significant alluvial deposits of the stone could then be found along the rivers Penner, Krishna and Godavari. It is unclear when diamonds were first mined in India, although estimated to be at least 5,000 years ago.[222] India remained the world's only source of diamonds until the discovery of diamonds in Brazil in the 18th century.[223][224][225] Golconda served as an important centre for diamonds in central India.[226] Diamonds then were exported to other parts of the world, including Europe.[226] Early references to diamonds in India come from Sanskrit texts.[227] The Arthashastra of Kautilya mentions diamond trade in India.[225] Buddhist works dating from the 4th century BCE mention it as a well-known and precious stone but don't mention the details of diamond cutting.[219] Another Indian description written at the beginning of the 3rd century describes strength, regularity, brilliance, ability to scratch metals, and good refractive properties as the desirable qualities of a diamond.[219] A Chinese work from the 3rd century BCE mentions: "Foreigners wear it [diamond] in the belief that it can ward off evil influences".[219] The Chinese, who did not find diamonds in their country, initially used diamonds as a "jade cutting knife" instead of as a jewel.[219]
  • Zinc mining and medicinal zinc – Zinc was first smelted from zinc ore in India.[228] Zinc mines of Zawar, near Udaipur, Rajasthan, were active during early Christian era.[229][230] There are references of medicinal uses of zinc in the Charaka Samhita (300 BCE).[231] The Rasaratna Samuccaya which dates back to the Tantric period (c. 5th – 13th century CE) explains the existence of two types of ores for zinc metal, one of which is ideal for metal extraction while the other is used for medicinal purpose.[231][232] India was to melt the first derived from a long experience of the old alchemy zinc by the distillation process, an advanced technique. The ancient Persians had also tried to reduce zinc oxide in an open stove, but had failed. Zawar in Tiri valley of Rajasthan is the first known old zinc smelting site in the world.[citation needed] The distillation technique of zinc production dates back to the 12th century CE and is an important contribution of India in the world of science.

Space

edit

Miscellaneous

edit
  • Punch (drink) a mixed drink containing fruits or fruit juice that can be both alcoholic and non-alcoholic originated in the Indian subcontinent before making its way into England by passage through the East India Company.[242] This beverage is very popular among the world with many varietal flavors and brands throughout the beverage industry.
  • Hookah or water pipe: according to Cyril Elgood (PP.41, 110), the physician Irfan Shaikh, at the court of the Mughal emperor Akbar I (1542–1605) invented the Hookah or water pipe used most commonly for smoking tobacco.[243][244][245][246]

Modern India

edit

Medicine

edit
  • NexCAR19, is designed to target cancer cells carrying the CD19 protein, a marker on cancer cells, enhancing precision in treatment.[247]
  • Urea stibamine – Sir Upendranath Brahmachari synthesised urea-stibamine (carbostibamide) in 1922 and determined that it was an effective treatment for kala-azar (visceral leishmaniasis).
  • post-kala-azar dermal leishmaniasis – n 1922, Brahmachari also discovered a new, deadly form of leishmaniasis. He called it dermal leishmanoid, marked by the appearance of sudden eruptions on the face of the patients without fever or other complaints. He observed it as a disease in partially cured cases of kala-azar, along with those who had no history of the disease at all.[248] It has since been termed as post-kala-azar dermal leishmaniasis.
  • Cholera toxin – Cholera toxin was discovered in 1959 by Indian microbiologist Sambhu Nath De.[249]
  • In vitro fertilisation – the second successful birth of a 'test tube baby' occurred in India just 67 days after Louise Brown was born. The girl, named Durga, was conceived in vitro using a method developed independently by Subhash Mukhopadhyay, a physician and researcher from Kolkata. Mukhopadhyay had been performing experiments on his own with primitive instruments and a household refrigerator.[250] However, state authorities prevented him from presenting his work at scientific conferences,[251] and it was many years before Mukhopadhyay's contribution was acknowledged in works dealing with the subject.[252][better source needed]
  • Cervical cerclage – was first described by V. N. Shirodkar in Bombay in 1955.[253]

Electronics and communications

edit
  • Horn antenna or microwave horn, One of the first horn antennas was constructed by Jagadish Chandra Bose in 1897.[254][255]
  • Microwave communication – The first public demonstration of microwave transmission was made by Jagadish Chandra Bose, in Calcutta, in 1895, two years before a similar demonstration by Marconi in England, and just a year after Oliver Lodge's commemorative lecture on Radio communication, following Hertz's death. Bose's revolutionary demonstration forms the foundation of the technology used in mobile telephony, radars, satellite communication, radios, television broadcast, WiFi, remote controls and countless other applications.[256][257]
  • Low Mobility Large cell (LMLC), is a feature of 5G and is designed to enhance the signal transmission range of a basestation several times, helping service providers cost-effectively expand coverage in rural areas.[258]
  • WaveguideJagadish Chandra Bose researched millimetre wavelengths using waveguides, and in 1897 described to the Royal Institution in London his research carried out in Kolkata.[259]
  • Phantom connectivity, a system for providing a higher level security to data communication in computer networks developed by ISRO. Phantom connectivity model enables organization to copy users download data from Internet to Intranet without connecting both the networks.[260]

Computers and programming languages

edit

Construction, civil engineering and architecture

edit
  • Coal Mine to PSP, Coal India will turn abandoned mines or de-coaled mine to Pumped Storage Projects(PSP) with help of NHPC hence saving huge amount of capital for development of reservoir or dams.[271]
  • CO2-treated-C&D, researchers at the Centre for Sustainable Technologies (CST), IISc, are exploring ways to store carbon dioxide from industrial flue gas in excavated soil in Construction and Demolition (C&D) waste. the effect of injecting carbon dioxide gas into clayey soil—typically excavated from construction sites. This resulted in better stabilization of clay by cement and lime, and reduced the surface area, pore volume and lime reactivity of clay in soil, thereby improving the bulk engineering performance of the material.[272][273]
  • Chenab rail bridge, is the world's first blast proof bridge.[274]
  • Rib & spine/Spine & Wing technique, NHAI has developed a flyover design which allows to save cost, time, minimum material usage and allows light under the flyover using the same technique.
  • (I)-TM Tunneling technique:(I)-TM as Himalayan tunnelling method for tunnelling through the Himalayan geology to build tunnels in Jammu and Kashmir. Engineers decided to provide rigid supports using 'ISHB' as against the lattice girder method used in the New Austrian Tunnelling Method.ISHB uses nine-metre pipes in the mountains. It is called pipe roofing. Engineers made an umbrella using these perforated poles and filled them with PU grout.[275][276][277]
  • waterproof roads, zydex industries has developed waterproof road by forming a skin like layer that is water resistant using inhouse silane nanotechnology.[278][279]
  • Plastic road are made entirely of plastic or of composites of plastic with other materials. Plastic roads are different from standard roads in the respect that standard roads are made from asphalt concrete, which consists of mineral aggregates and asphalt. Most plastic roads sequester plastic waste within the asphalt as an aggregate. Plastic roads first developed by Rajagopalan Vasudevan in 2001[280][281][282]

Finance and banking

edit
  • Payments bank is an Indian new model of banks conceptualised by the Reserve Bank of India (RBI) without issuing credit.

Paleontology

edit
  • In 2024, one of the longest snakes to ever exist, Vasuki indicus, was discovered by scientists from the Indian Institute of Technology. The snake was estimated to be between 10.9 and 15.2 metres in length and lived 47 million years ago. The fossilised vertebrae of Vasuki indicus were discovered in a lignite mine in Gujarat. It was likely a slow moving predator who killed its prey through constriction.[283]
  • In 2018, scientists from the Geological Survey of India and the Indian Institute of Technology discovered the fossil remains of a previously unknown dinosaur species in the Thar Desert region of Jaisalmer, Rajasthan. The dinosaur is named Tharosaurus indicus, after the Thar Desert and India.[284]

Zoology

edit
  • The world's first white tiger was Mohan, a mutant Bengal tiger captured in 1951 by Maharaja Martand Singh of Rewa. These type of tiger are found in White Tiger Safari & Zoo Mukundpur

Genetics

edit
  • Amrapali mango – A named mango cultivar introduced in 1971 by Dr. Pijush Kanti Majumdar at the Indian Agriculture Research Institute in Delhi.
  • Asmon, is a plant based drug that is used to treat bronchial asthma developed by CSIR.[285]
  • Mynvax – The world's first "warm" COVID-19 vaccine, developed by IISc, capable of withstanding 37 °C (99 °F) for a month and neutralise all coronavirus variants of concern.[286]
  • ZyCoV-D vaccine – The world's first DNA-based vaccine for humans.[287]

Metallurgy, manufacturing, and industry

edit
  • Carbon nitride solar reactor – In September 2021, A team from the Institute of Nano Science and Technology (INST), Mohali, has fabricated a prototype reactor which operates under natural sunlight to produce hydrogen at a scale of around 6.1 litres in eight hours. They have used an earth-abundant chemical called carbon nitrides as a catalyst for the purpose.[288][289]
  • High ash coal gasification (coal to methanol) – The central government gave the country world's first 'coal to methanol' (CTM) plant built by the Bharat Heavy Electricals Limited (BHEL). The plant was inaugurated in BHEL's Hyderabad unit, The pilot project is the first that uses the gasification method for converting high-ash coal into methanol. Handling of high ash and heat required to melt this high amount of ash is a challenge in the case of Indian coal, which generally has high ash content. Bharat Heavy Electricals Limited has developed the fluidized bed gasification technology suitable for high ash Indian coals to produce syngas and then convert syngas to methanol with 99% purity.[290]
  • High Nitrogen Steel, Jindal Stainless was the first company to commercially produce High Nitrogen Steel at Industrial scale, originally developed by DRDO. HNS are very good for defence and blast protection application.[291]
  • Controlled shunt reactor – In 2002, Bharat Heavy Electricals Limited has successfully developed a first-of-its-kind in the world device for improving power transfer capability and reducing transmission losses in the country's highest rating (400 kV) transmission lines.The device is called Controlled Shunt Reactor.[292][293]
  • DMR 1700 steel – For several high-technology applications, such as military hardware and aerospace, need to possess ultrahigh strength (UHS; minimum yield strength of 1380 MPa (200 ksi)) coupled with high fracture toughness in order to meet the requirement of minimum weight while ensuring high reliability.
  • DMR SN 742 is a nickel-based superalloy developed by the Defence Metallurgical Research Laboratory (DMRL) in India. It is specifically designed for aero-engine applications, such as high-pressure compressors (HPC) and turbine rotors (HPT) in gas turbine engines.[294][295]
  • GTM-900 is a high-temperature alpha-beta titanium alloy developed by National Aerospace Laboratories and DMRL used for components like compressor blades due to its strength and creep resistance at elevated temperatures.[296][297]
  • TITAN 26A and TITAN 29A, These are high-performance titanium-based alloys which are known for their high strength, creep resistance, and corrosion resistance, particularly in high-temperature environments.[298]
  • Magnesium-lithium alloy grade(Mg-9Li-7.5Al-1.2Sn), ISRO has successfully mastered melting and casting of this alloy using inert atmosphere. It is now possible to melt up to 20 kg of this alloy and gave stable properties up to 1000C.[299][300]
  • JD-1 alloy – A special lightweight alloy developed by Jindal Defence with a minimum guaranteed hardness of 500 HB. It can be used in aerospace, small arms, and engineering solutions. It is mainly used in armoured jacket.
  • Polymetallic nodules, India is considered a pioneer in the exploration of polymetallic nodules, In 1981, Indian scientists recovered manganese nodules, marking the beginning of deep sea exploration in the country.In 1987, India became the first country to receive Pioneer Investor status from the International Seabed Authority (ISA).[301][302]
  • Sorption-enhanced steam methane reforming (SESMR) – In April 2022, the scientists from CSIR-Indian Institute of Chemical Technology (CSIR-IICT), Hyderabad developed a fluidized bed reactor (FBR) facility in Hyderabad to perform sorption enhanced steam methane reforming (SESMR) to achieve clean hydrogen in its purest form. The team of scientists have designed a hybrid material to simulate capturing carbon dioxide in-situ (onsite) and converting it into clean hydrogen from non-fuel grade bioethanol.[303]
  • Spray-drying buffalo milk – The collective consensus of dairy experts worldwide was that buffalo milk could not be spray-dried due to its high fat content. Harichand Megha Dalaya & his invention of the spray dry equipment, led to the world's first buffalo milk spray-dryer, at Amul Dairy in Gujarat.
  • Neem-coated urea is an agriculture fertilizer in which the urea is neem oil-coated. The coating of neem slows the nitrification of urea thereby helps in increased absorption of nutrients in the soil as well as reduces groundwater pollution.[304]
  • Jackal steel – An advanced grade high-strength, low-alloy steel. The technology of Jackal steel has been passed on to Steel Authority of India Limited (SAIL) and MIDHANI for its bulk production.
  • High-Rise Pantograph – The new-design world record pantograph, developed completely in-house for use in DFC & other freight routes with height of 7.5 metres (25 ft).[305]
  • Commercial CCU plant: Tuticorin Alkali Chemicals and Fertilizers Limited (TFL) partnered with Carbon Clean to create the world's first fully commercial CCU plant. The 10 MW facility captures coal-fired boiler flue gas and uses it to deliver industrial quality CO2. The 10 MW facility captures coal-fired boiler flue gas and uses it to deliver industrial quality CO2.[306] The technology has been developed by Carbon Clean Solutions, headquartered in London – a start-up by two Indian engineers focusing on carbon dioxide separation technology.There are many chemicals exported out of India where CO2 is the raw material.[307]
  • Triple-stack container freight train[308][309] – In order to ensure new streams of traffic and commodities and to bring about a modal shift, the DFC is undertaking trials for running smaller than usual containers, known as dwarf containers (where the container height is lower by 660 mm than normal containers), in triple-stack formation to further improve the profitability of train operations. It may be possible to run these as double-stack on conventional routes and triple-stack on routes with high-rise OHE, once the trials are successfully completed.[310]

Metrology

edit
 
Crescograph, Bose Institute, Kolkata

Rocket science and jet propulsion

edit

Science and technology

edit
  • Bipyrazole Organic Crystals, the piezoelectric molecules developed by IISER scientists recombine following mechanical fracture without any external intervention, autonomously self-healing in milliseconds with crystallographic precision.[320]
  • SEBEX 2, is a high performance explosive, it is said to be 2.01 times more lethal than TNT and most powerful non-nuclear explosives in the world. The Indian Navy has certified the explosive.[321]
  • Silica fiber based composite or Silica-Silica composite, In 2012 ISRO developed world's first pure silica fiber composite without carbon element known as silica fiber-silica matrix composite and also a new technology for developing silica fibres by sol-gel process. These fibres can be used for high temperature insulation up to 1500C and cheaper than Carbon fiber composite. Silica-silica composite are prepared by leaching glass cloth with hydrochloric acid, rinsing to remove acid therefrom, vacuum drying, moulding and treating with ethyl silicate and cationic starch binder further drying and sintering.[322][323][324]
  • Single-crystalline Scandium Nitride, that has the ability to convert infrared light into energy, Scientists based in Jawaharlal Nehru Centre for Advanced Scientific Research (JNCASR), Bengaluru have discovered a novel material that can emit, detect, and modulate infrared light with high efficiency making it useful for solar and thermal energy harvesting and for optical communication devices.[325][326]
  • Low-threshold gain lasers, researchers from IISER, Bhopal have made a breakthrough in field of low threshold gain lasers using crystals of cesium lead bromide they are able to produce high-intensity lasers with very low energy output.[327]
  • Indian Ocean Dipole is an unusual pattern in the ocean-atmosphere system of the equatorial Indian Ocean that influences the monsoon and can offset the adverse impact of El Nino. It is typically characterized by cooler than normal eastern equatorial Indian Ocean and warmer than normal west and unusual equatorial easterly winds. It was discovered in Centre for Atmospheric And Oceanic Sciences, IISc. team led by NH Saji in 1999.[328]
  • Iron Ion battery,In 2019 world's 1st iron-ion battery was first invented by team of researchers in IIT Madras.[329]
  • Solution combustion synthesis (SCS) was accidentally discovered in 1988 at Indian Institute of Science (IISc), Bengaluru, India. SCS involves an exothermic redox chemical reaction between an oxidizer like metal nitrate and a fuel in an aqueous medium.[330]
  • Nalgonda Technique is a technique for deflouridation to reduce the flouride levels in water developed by National Environmental Engineering Research Institute, Nagpur.[331][332]
  • Electrically Excited Synchronous Motor (EESM) or Rare earth free motor: In 2021 deep-tech startup Chara Technologies has built scalable, cloud-controlled electric vehicle motors free of toxic rare-earth metals, thus cutting a massive dependency on imports to accelerate electric mobility in India.[333][334]
  • MD-15 is a new methanol fuel grade in which Methanol is blended with diesel. Research Design and Standards Organisation (RDSO), in collaboration with the Indian Oil Corporation Ltd (IOCL), has developed a special cost-effective fuel that would not only minimize IR's dependency on diesel, but will also be emit fewer pollutants. IOCL developed the composition, adding 14% additives (developed indigenously by IOCL) along with 71% mineral diesel, 15% methanol. MD-15 fuelled engine has shown superior performance, emission and combustion characteristics than the mineral diesel fuelled engine.[335][336]
  • Unified Payments Interface – An instant real-time bank to bank payments protocol system developed by National Payments Corporation of India (NPCI) facilitated by QR code and Virtual Private Address(VPA) or UPI ID. UPI has able to make India a cashless and cardless economy, also strain on ATM infrastructure has reduced significantly.
  • Digital rupee (e₹) or eINR or e-rupee is a world's first digital national currency, to be issued by the Reserve Bank of India (RBI) as a central bank digital currency (CBDC). Digital Rupee is using blockchain distributed-ledger technology. Digital rupee users to hit 50,000 by Jan-end on better acceptance.[337]

Weapon systems

edit
  •  
    A diagram of the fuel-cell AIP module developed by the DRDO of India, it can power ships or any other marine transport
    ATAGS – Bharat Forge and the DRDO has developed world's first electric artillery gun[338]
  • Rifle-rated ballistic helmet, MKU has developed what it bills as "a first-of-its-kind rifle-rated ballistic helmet", MKU states that the Kavro Doma 360 is "the first anti-rifle helmet in the world that does not have bolts or any metal parts"[339]
  • Critical Situation Response Vehicle (CSRV) – The Central Reserve Police Force (CRPF) has made and inducted a bomb/bulletproof armoured vehicle. The latest all-terrain highly sophisticated vehicle 'CSRV' has given a shot in the arm to the Central Reserve Police Force engaged in counter-terror operations.
  • E-bomb – The Defence Research and Development Organisation (DRDO) has been developing an e-bomb which will emit electromagnetic shock waves that destroy electronic circuits and communication networks of enemy force.[340] The tow bodies in Lakshya-2 Weapon Delivery Configuration carry High Energy Weapon Payload.[341]
  • Phosphoric Acid Fuel Cell air-independent propulsion (PAFC AIP) is a 270 kilowatt phosphoric acid fuel cell (PAFC) air-independent propulsion (AIP) system to power the Kalvari-class submarines is developed by the Naval Materials Research Laboratory of Indian Defence Research and Development Organisation in collaboration with Larsen & Toubro and Thermax. The patent is owned by DRDO. Its application is considered to be wide and it can also power ships in future.[342]

Automotive innovations

edit
  • Helmet AC - Featuring a plastic top and built-in-fan-like structure, the AC helmets are powered by a battery pack, which is worn by the traffic police officials on their waist. These helmets work for around 8 hours on a single full charge.[343]
  • CNG car/vehicle – Bajaj Auto launched the first 'commercial' lot of its CNG (Compressed Natural Gas) autorickshaws in Delhi on 29 May 2000.By 1 December 2002, the last diesel bus had disappeared from Delhi’s roads, all buses were running on CNG.At the beginning of 2005, 10,300 CNG busses, 10,000 CNG taxis and 10,000 CNG cars run on Delhi’s roads.[344]

Mathematics

edit

Sciences

edit
 
Bengali Chemist Prafulla Chandra Roy synthesised NH4NO2 in its pure form.
 
A Ramachandran plot generated from the protein PCNA, a human DNA clamp protein that is composed of both beta sheets and alpha helices (PDB ID 1AXC). Points that lie on the axes indicate N- and C-terminal residues for each subunit. The green regions show possible angle formations that include Glycine, while the blue areas are for formations that don't include Glycine.

Space

edit
 
Direct evidence of lunar water in the Moon atmosphere obtained by the Chandrayaan-1's Altitudinal Composition (CHACE) output profile

See also

edit

Notes

edit
  1. ^ Greek astronomer Hipparchus (c. 190 – c. 120 BC) centuries earlier also calculated sidereal year to be 365 + 1/4 + 1/144 days (365.25694... days ie., 365 days 6 hours 10 min) .[234]

References

edit
  1. ^ Nanda, Meera (16 September 2016), "Hindutva's science envy", Frontline, retrieved 14 October 2016
  2. ^ a b c Kriger & Connah (2006), page 120
  3. ^ a b c d Encyclopædia Britannica (2008). jute.
  4. ^ a b Kenneth F.Kiple & Kriemhild Conee Ornelas. "World history of Food – Sugar". Cambridge University Press. Retrieved 9 January 2012.
  5. ^ Book Two of Dioscorides' Materia Medica. The book is downloadable from links at the Wikipedia Dioscorides page.
  6. ^ de materia medica.
  7. ^ Kieschnick (2003)
  8. ^ a b Kieschnick (2003), page 258
  9. ^ a b Livingston & Beach, 19
  10. ^ a b c Encyclopædia Britannica (2008). Pagoda.
  11. ^ Asher 2015, pp. 1–5.
  12. ^ Kumar (2018).
  13. ^ "History | District Nalanda, Government of Bihar | India". nalanda.nic.in. 15 June 2023. Retrieved 2 June 2023.
  14. ^ "UNESCO Nominations" (PDF). UNESCO. Retrieved 2 June 2023.
  15. ^ Pinkney 2015, pp. 111–149.
  16. ^ "Reserve Bank of India – Publications".
  17. ^ Arasu, S. T. (4 July 2020). "Galah Panjang and its Indian roots". On the sport. Be part of it. Retrieved 6 August 2023.
  18. ^ "Badminton Alberta". www.badmintonalberta.ca. Retrieved 13 July 2022.
  19. ^ Biswas, Sudipta (4 January 2022). "Poona: Where Badminton Was Invented". www.livehistoryindia.com. Retrieved 13 July 2022.
  20. ^ American Chess Bulletin, vol. 13–15, Hartwig Cassell & Hermann Helms, eds.
  21. ^ History of Physical Education, p.209, SR Tiwari, APH Publishing
  22. ^ "All India Carrom Federation". Archived from the original on 16 February 2015. Retrieved 2 February 2015.
  23. ^ "Carrom.org". Archived from the original on 1 February 2015. Retrieved 2 February 2015.
  24. ^ Murray (1913)
  25. ^ Forbes (1860)
  26. ^ a b Jones, William (1807). "On the Indian Game of Chess". pages 323–333
  27. ^ Linde, Antonius (1981)
  28. ^ Wilkinson, Charles K (May 1943)
  29. ^ Bird (1893), page 63
  30. ^ Hooper & Whyld (1992), page 74
  31. ^ Sapra, Rahul (2000). "Sports in India". Students' Britannica India (Vol. 6). Mumbai: Popular Prakashan. p. 106. ISBN 0-85229-762-9.
  32. ^ a b Meri (2005), page 148
  33. ^ a b Basham (2001), page 208
  34. ^ a b c Encyclopædia Britannica (2002). Chess: Ancient precursors and related games.
  35. ^ Encyclopædia Britannica (2007). Chess: Introduction to Europe.
  36. ^ a b Alter, page 88
  37. ^ Meera, Sethumadhavan; Vinodan, A. (23 September 2019). "Attitude towards alternative medicinal practices in wellness tourism market". Journal of Hospitality and Tourism Insights. 2 (3): 278–295. doi:10.1108/JHTI-06-2018-0037.
  38. ^ Radhakrishnan, S. Anil (10 January 2021). "Kalaripayattu academy braces for action". The Hindu. Retrieved 17 May 2021.
  39. ^ "The Evolution of Kho Kho Mats in India: A Historical Overview". News18. 29 May 2023. Retrieved 6 August 2023.
  40. ^ a b c MSN Encarta (2008). Pachisi.
  41. ^ মজার খেলা নুনতা (in Bengali). 19 September 2012. Archived from the original on 23 June 2013. Retrieved 22 May 2013.
  42. ^ "Terra cotta discs | Harappa". harappa.com. Retrieved 7 March 2021.
  43. ^ a b Augustyn, pages 27–28
  44. ^ a b James McManus (27 October 2009). Cowboys Full: The Story of Poker. Macmillan. p. 34. ISBN 978-0-374-29924-8.
  45. ^ Carlisle, Rodney (2009), Encyclopedia of Play in Today's Society, SAGE Publications, p. 31, ISBN 978-1-4129-6670-2
  46. ^ Quackenbos (2010), Illustrated History of Ancient Literature, Oriental and Classical, READ BOOKS, p. 60, ISBN 978-1-4455-7978-8
  47. ^ Kapoor, Subodh (2002), The Indian encyclopaedia: biographical, historical, religious, administrative, ethnological, commercial and scientific – Vol 6, Genesis Publishing Pvt Ltd, p. 1786, ISBN 978-81-7755-257-7
  48. ^ Townsend, George (1862), The manual of dates: a dictionary of reference to all the most important events in the history of mankind to be found in authentic records, Routledge, Warne, & Routledge, p. 184
  49. ^ Needham, Joseph (2004). Science & Civilisation in China. Vol. V:1. Cambridge University Press. pp. 131–132. ISBN 978-0-521-05802-5.
  50. ^ David G. Schwartz (5 October 2006). Roll the bones: the history of gambling. Gotham Books. ISBN 978-1-59240-208-3.
  51. ^ WashingtonPost.com. Accessed 2 August 2012. Archived 3 January 2019 at the Wayback Machine
  52. ^ "Vajra-musti Indian Sport". www.topendsports.com. Retrieved 21 July 2022.
  53. ^ Kesting, Stephan (13 March 2012). "The Ancient Vale Tudo of India: Vajramushti". Grapplearts. Retrieved 21 July 2022.
  54. ^ a b Hesse, Rayner W. & Hesse, Rayner W. Jr. (2007). Jewelrymaking Through History: An Encyclopedia. Greenwood Publishing Group. 35. ISBN 0-313-33507-9.
  55. ^ McNeil, Ian (1990). An encyclopaedia of the history of technology. Taylor & Francis. 852. ISBN 0-415-01306-2.
  56. ^ a b c d Encyclopædia Britannica (2008). calico
  57. ^ a b c d Baber (1996), page 57
  58. ^ Encyclopædia Britannica (2008). cashmere.
  59. ^ Encyclopædia Britannica (2008). kashmir shawl.
  60. ^ Smith, C. Wayne; Cothren, J. Tom (1999). Cotton: Origin, History, Technology, and Production. Vol. 4. John Wiley & Sons. pp. viii. ISBN 978-0471180456. The first improvement in spinning technology was the spinning wheel, which was invented in India between 500 and 1000 A.D.
  61. ^ a b Encyclopædia Britannica (2008). chintz
  62. ^ Hāṇḍā (1998), page 133
  63. ^ Stein (1998), page 47
  64. ^ Wisseman & Williams (1994), page 127
  65. ^ The Columbia Encyclopedia, Sixth Edition. cotton.
  66. ^ Angela Lakwete: Inventing the Cotton Gin: Machine and Myth in Antebellum America, The Johns Hopkins University Press, 2003, ISBN 0-8018-7394-0, p. 5
  67. ^ Baber (1996), page 56
  68. ^ Irfan Habib, Economic History of Medieval India, 1200–1500, page 53, Pearson Education
  69. ^ Irfan Habib (2011), Economic History of Medieval India, 1200–1500, pp. 53–54, Pearson Education
  70. ^ Encyclopædia Britannica (2008). interior design
  71. ^ a b Encyclopædia Britannica (2008). crewel work
  72. ^ a b Encyclopædia Britannica (2008). quilting
  73. ^ a b Barker, page 13
  74. ^ a b Beer, page 60
  75. ^ a b Wise, page 11–12
  76. ^ Possehl, Gregory L. (1996). Mehrgarh in Oxford Companion to Archaeology, edited by Brian Fagan. Oxford University Press.
  77. ^ Irfan Habib (2011), Economic History of Medieval India, 1200–1500, p. 53, Pearson Education
  78. ^ a b c Todd, Jan (1995). From Milo to Milo: A History of Barbells, Dumbells, and Indian Clubs Archived 31 July 2012 at the Wayback Machine. Accessed in September 2008. Hosted on the LA84 Foundation Sports Library.
  79. ^ cā̃po (चाँपो IPA: [tʃãːpoː]) is the imperative of cā̃pnā (चाँपना IPA: [tʃãːpnaː]), "to smear, knead the muscles, massage the head and hair"
  80. ^ Douglas Harper. "Online Etymology Dictionary". Retrieved 14 July 2007.
  81. ^ Bisht (1993). "Paleobotanical and pollen analytical investigations" (PDF). Indian Archaeology a Review 1993–1994: 143–144.
  82. ^ kSuNa, Sanskrit Lexicon, Monier-Williams Dictionary (1872)
  83. ^ phenaka, Spoken Sanskrit, University of Koeln, Germany
  84. ^ Rahman, History of Indian Science, Technology and Culture at Google Books, Oxford University Press, ISBN 978-0195646528, page 145
  85. ^ Tamil Nadu Medicinal plants board Archived 21 July 2011 at the Wayback Machine
  86. ^ Tamil Nadu Agricultural university – Albizzia amara
  87. ^ Khushwant Singh, Hymns of Guru Nanak, Orient Longman, ISBN 978-8125011613
  88. ^ Virginia Smith (2007), Clean: A History of Personal Hygiene and Purity, Oxford University Press, ISBN 978-0199297795
  89. ^ "bose real inventor" (PDF).
  90. ^ Dwivedi, Girish; Dwivedi, Shridhar (2007). "Sushruta – the Clinician – Teacher par Excellence" (PDF). The Indian Journal of Chest Diseases and Allied Sciences. 49: 243–4. Archived from the original (PDF) on 10 October 2008.
  91. ^ Zysk, K. G. (1991). Asceticism and Healing. London, New York, Delhi: Oxford University Press. ISBN 978-0-19-505956-4.
  92. ^ Chopra 2003, p. 75
  93. ^ Zvelebil, Kamil V. (1996). The Siddha Quest for Immortality. Oxford: Mandrake of Oxford. ISBN 978-1-869928-43-8.
  94. ^ Scharf, Hartmut (1999). "The Doctrine of the Three Humors in Traditional Indian Medicine and the Alleged Antiquity of Tamil Siddha Medicine". Journal of the American Oriental Society. 119 (4): 609–629. doi:10.2307/604837. JSTOR 604837.
  95. ^ Kearns & Nash (2008)
  96. ^ Lock; Last & Dunea (2001), page 420
  97. ^ a b Lock; Last & Dunea (2001), page 836
  98. ^ Nobel Foundation (2008). The Nomination Database for the Nobel Prize in Physiology or Medicine, 1901–1951
  99. ^ a b Upendra Nath Brahmachari: A Pioneer of Modern Medicine in India. Vigyan Prasar: Government of India
  100. ^ Rinzler 2009, p. 151.
  101. ^ Wujastyk, Dominik (2003). The Roots of Ayurveda (3 ed.). Penguin. pp. 63–100. ISBN 0-140-44824-1.
  102. ^ McNeill RA (June 1960). "A History of Tonsillectomy: Two Millennia of Trauma, Haemorrhage and Controversy". The Ulster Medical Journal. 29 (1): 59–63. PMC 2384338. PMID 20476427.
  103. ^ Lurie, Samuel (April 2005). "The changing motives of cesarean section: from the ancient world to the twenty-first century". Archives of Gynecology and Obstetrics. 271 (4): 281–285. doi:10.1007/s00404-005-0724-4. PMID 15856269.
  104. ^ Lurie S (April 2005). "The changing motives of cesarean section: from the ancient world to the twenty-first century". Archives of Gynecology and Obstetrics. 271 (4): 281–285. doi:10.1007/s00404-005-0724-4. PMID 15856269. S2CID 26690619.
  105. ^ Chamberlin (2007), page 80
  106. ^ a b Hobson (2004), page 103
  107. ^ a b c d Woods & Woods (2000), pages 52–53
  108. ^ "16.17.4: Stirrups". Encyclopaedia of Indian Archaeology (Vol. 1). Edited by Amalananda Ghosh (1990). page 336
  109. ^ Azzaroli (1985), page 156
  110. ^ a b Addington (1990), page 45
  111. ^ a b Barua (2005), pages 16–17
  112. ^ a b "The origins of Iron Working in India: New evidence from the Central Ganga plain and the Eastern Vindhyas by Rakesh Tewari (Director, U.P. State Archaeological Department)" (PDF). antiquity.ac.uk. Retrieved 13 April 2015.
  113. ^ Marco Ceccarelli (2000). International Symposium on History of Machines and Mechanisms: Proceedings HMM Symposium. Springer. ISBN 0-7923-6372-8. pp 218
  114. ^ I. M. Drakonoff (1991). Early Antiquity. University of Chicago Press. ISBN 0-226-14465-8. pp 372
  115. ^ Balasubramaniam, R. (2000). "On the Corrosion Resistance of the Delhi Iron Pillar" (PDF). Corrosion Science. 42 (12): 2103–29. Bibcode:2000Corro..42.2103B. doi:10.1016/s0010-938x(00)00046-9.
  116. ^ a b Juleff, G (1996). "An ancient wind powered iron smelting technology in Sri Lanka". Nature. 379 (6560): 60–63. Bibcode:1996Natur.379...60J. doi:10.1038/379060a0. S2CID 205026185.
  117. ^ "Archaeological remains of a Harappa Port-Town, Lothal". UNESCO World Heritage Centre. Retrieved 10 February 2022.
  118. ^ "This is Modi govt's plan for India's first National Maritime Museum in Gujarat's Lothal". ThePrint. 9 March 2020.
  119. ^ a b Gwinnett, A. John; Gorelick, Leonard (1991). "Bead Manufacture at Hajar Ar-Rayhani, Yemen". The Biblical Archaeologist. 54 (4): 187–196. doi:10.2307/3210280. JSTOR 3210280.
  120. ^ Keene, Manuel (1981). "THE LAPIDARY ARTS IN ISLAM". Penn Museum. Retrieved 31 July 2020.
  121. ^ Irfan Habib (2011), Economic History of Medieval India, 1200–1500, page 53, Pearson Education
  122. ^ For the etching technique, see MacKay, Ernest (1925). "Sumerian Connexions with Ancient India". The Journal of the Royal Asiatic Society of Great Britain and Ireland (4): 699. JSTOR 25220818.
  123. ^ Guimet, Musée (2016). Les Cités oubliées de l'Indus: Archéologie du Pakistan (in French). FeniXX réédition numérique. p. 355. ISBN 9782402052467.
  124. ^ "Such beads occur fairly largely on all the principal sites of the Harappan civilisation." in Pakistan Archaeology No.2. 1965. p. 21.
  125. ^ Saju, M. T. (17 November 2020). "Indians made glass blown beads 2,500 years ago". The Times of India. Retrieved 6 March 2021.
  126. ^ Francis, Peter (1990). "Glass Beads in Asia Part Two. Indo-Pacific Beads". Asian Perspectives. 29 (1): 1–23. JSTOR 42928207.
  127. ^ a b Wood, Marilee (June 2012). "Interconnections: glass beads and trade in southern and eastern Africa and the Indian Ocean - 7th to 16th centuries AD". Azania. 47 (2): 248. doi:10.1080/0067270X.2012.680307.
  128. ^ a b c Kuppuram, Govindarajan (1989). Ancient Indian Mining, Metallurgy, and Metal Industries. Sundeep Prakashan. ISBN 978-81-85067-28-5.
  129. ^ a b Krishnan, M.V. (1976). Cire perdue casting in India. Kanak Publications.
  130. ^ a b Agrawal, D. P. (2000). Ancient Metal Technology and Archaeology of South Asia. A Pan-Asian Perspective. New Delhi: Aryan Books International. ISBN 978-81-7305-177-7.
  131. ^ a b Kenoyer, J. M. & H. M.-L. Miller, (1999). Metal Technologies of the Indus Valley Tradition in Pakistan and Western India., in The Archaeometallurgy of the Asian Old World., ed. V. C. Pigott. Philadelphia: The University of Pennsylvania Museum.
  132. ^ Kamarustafa (1992), page 48
  133. ^ a b Savage-Smith, Emilie (1985). Islamicate Celestial Globes: Their history, Construction, and Use. Smithsonian Institution Press, Washington, D.C.
  134. ^ Satyawadi, Sudha (1 July 1994). Proto-Historic Pottery of Indus Valley Civilization; Study of Painted Motif. D.K. Printworld. p. 324. ISBN 978-8124600306.
  135. ^ Blackman, M. James; et al. (1992). The Production and Distribution of Stoneware Bangles at Mohenjo-daro and Harappa as Monitored by Chemical Characterization Studies. Madison, WI, USA: Prehistory Press. pp. 37–44.
  136. ^ Mark Kenoyer, Jonathan (1998). Ancient Cities of the Indus Valley Civilization. Oxford University Press. p. 260.
  137. ^ Wood, Marilee; Dussubieux, Laure; Robertshaw, Peter (2012). "The Glass of Chibuene, Mozambique: New Insights into Early Indian Ocean Trade". South African Archaeological Bulletin. 67 (195): 59–74.
  138. ^ Wood, Marilee; Panighello, Serena; Orsega, Emilio F.; Robertshaw, Peter; van Elteren, Johannes T.; Crowther, Alison; Horton, Mark; Boivin, Nicole (August 2017). "Zanzibar and Indian Ocean trade in the first millennium CE: the glass bead evidence". Archaeological and Anthropological Sciences. 9 (5): 879–901. Bibcode:2017ArAnS...9..879W. doi:10.1007/s12520-015-0310-z. hdl:11858/00-001M-0000-0029-7CD9-0.
  139. ^ Kenoyer, J. Mark; Vidale, Massimo (1992). "A New Look at Stone Drills of the Indus Valley Tradition". MRS Proceedings. 267. doi:10.1557/PROC-267-495.
  140. ^ Gwinnett, A. John; Gorelick, L. (1993). "Beads, Scarabs, and Amulets: Methods of Manufacture in Ancient Egypt". Journal of the American Research Center in Egypt. 30: 125–132. doi:10.2307/40000232. JSTOR 40000232.
  141. ^ Bellina, B. (March 2018). "The elaboration of political models in maritime Southeast Asia and of pan-regional culture: Contribution from Khao Sek stone ornament craft system study". Archaeological Research in Asia. 13: 13–24. doi:10.1016/j.ara.2017.06.002.
  142. ^ "WOOTZ STEEL: AN ADVANCED MATERIAL OF THE ANCIENT WORLD". materials.iisc.ernet.in. Archived from the original on 11 February 2019. Retrieved 23 July 2008.
  143. ^ Srinivasan 1994
  144. ^ Srinivasan & Griffiths
  145. ^ Sasisekaran, B; Raghunatha Rao, B (1999). "Technology of Iron and Steel in Kodumanal – An Ancient Industrial Centre in Tamilnadu" (PDF). Indian Journal of History & Science. 34 (4): 263–272. Archived from the original (PDF) on 23 September 2015.
  146. ^ "A great past in bright colours". Frontline. India. 8 October 2010. Archived from the original on 3 February 2011.
  147. ^ Sherby, Oleg D.; Wadsworth, Jeffrey (November 2001). "Ancient blacksmiths, the Iron Age, Damascus steels, and modern metallurgy". Journal of Materials Processing Technology. 117 (3): 347–353. doi:10.1016/S0924-0136(01)00794-4.
  148. ^ Ian Strangeways, A History of rain gauges, TerraData, 2010
  149. ^ Kosambi (1982) The Culture and Civilization of Ancient India in Historical Outline, p. 153, ISBN 978-0-7069-1399-6
  150. ^ Venable, Shannon L. (2011). Gold: A Cultural Encyclopedia. Santa Barbara, CA: ABC-CLIO, LLC. p. 264. ISBN 978-0313-384318.
  151. ^ a b Kenoyer, 265
  152. ^ a b In the third millennium BCE the Indus measuring system was further developed in the ancient regions of Iran and Afghanistan – Iwata, 2254.
  153. ^ a b Iwata2254
  154. ^ Baber, 23
  155. ^ MughalistanSipahi (19 June 2010). "Islamic Mughal Empire: War Elephants Part 3". Archived from the original on 13 December 2021. Retrieved 28 November 2012 – via YouTube.
  156. ^ Roddam Narasimha (1985), Rockets in Mysore and Britain, 1750–1850 A.D. Archived 27 September 2007 at the Wayback Machine, National Aeronautical Laboratory and Indian Institute of Science"Hyder Ali, prince of Mysore, developed war rockets with an important change: the use of metal cylinders to contain the combustion powder. Although the hammered soft iron he used was crude, the bursting strength of the container of black powder was much higher than the earlier paper construction. Thus a greater internal pressure was possible, with a resultant greater thrust of the propulsive jet. The rocket body was lashed with leather thongs to a long bamboo stick. Range was perhaps up to three-quarters of a mile (more than a kilometre). Although individually these rockets were not accurate, dispersion error became less important when large numbers were fired rapidly in mass attacks. They were particularly effective against cavalry and were hurled into the air, after lighting, or skimmed along the hard dry ground. Hyder Ali's son, Tippu Sultan, continued to develop and expand the use of rocket weapons, reportedly increasing the number of rocket troops from 1,200 to a corps of 5,000. In battles at Seringapatam in 1792 and 1799 these rockets were used with considerable effect against the British." – Encyclopædia Britannica (2008). rocket and missile.
  157. ^ A. Bowdoin Van Riper (29 October 2007). Rockets and Missiles: The Life Story of a Technology. JHU Press. pp. 14–. ISBN 978-0-8018-8792-5.
  158. ^ Narasimha, Roddam (27 July 2011). Rockets in Mysore and Britain, 1750–1850 A.D. (Report). National Aeronautical Laboratory and Indian Institute of Science.
  159. ^ Beckwith, Christopher I. (9 June 2015). Greek Buddha: Pyrrho's Encounter with Early Buddhism in Central Asia. Princeton University Press. ISBN 978-1-4008-6632-8.
  160. ^ Stephen Batchelor "Greek Buddha: Pyrrho's encounter with early Buddhism in central Asia", Contemporary Buddhism, 2016, pp 195–215
  161. ^ Charles Goodman, "Neither Scythian nor Greek: A Response to Beckwith's Greek Buddha and Kuzminski's "Early Buddhism Reconsidered"", Philosophy East and West, University of Hawai'i Press Volume 68, Number 3, July 2018 pp. 984–1006
  162. ^ Ganeri, Jonardon & Tiwari, Heeraman (eds.), (1988). The Character of Logic in India. Albany, NY, USA: State University of New York Press. ISBN 0-7914-3739-6 (HC:acid free), p.7-8
  163. ^ Ganeri, Jonardon (December 2002). "Jaina Logic and the Philosophical Basis of Pluralism". History and Philosophy of Logic. 23 (4): 267–281. doi:10.1080/0144534021000051505.
  164. ^ September 2017, Jessie Szalay-Live Science Contributor 18 (18 September 2017). "Who Invented Zero?". livescience.com. Retrieved 18 May 2021. {{cite web}}: |first= has generic name (help)CS1 maint: numeric names: authors list (link)
  165. ^ Nils-Bertil Wallin (19 November 2002). "The History of Zero". Yale Center for the Study of Globalization. Archived from the original on 25 August 2016. Retrieved 26 December 2011.
  166. ^ Dr. Hossein Arsham. "Zero in Four Dimensions". University of Baltimore. Retrieved 26 December 2011.
  167. ^ Devlin, Hannah (13 September 2017). "Much ado about nothing: ancient Indian text contains earliest zero symbol". The Guardian.
  168. ^ "Indian numerals". www-history.mcs.st-and.ac.uk. Retrieved 13 April 2015.
  169. ^ Salomon, R. (1998). Indian Epigraphy: A Guide to the Study of Inscriptions in Sanskrit, Prakrit, and the Other Indo-Aryan Languages. Oxford University Press, USA. p. 61. ISBN 9780195099843. Retrieved 13 April 2015.
  170. ^ a b c Smith (1958), pp. 257–258
  171. ^ a b Bourbaki (1998), page 49
  172. ^ Britannica Concise Encyclopedia (2007). algebra
  173. ^ a b c d e f g h i j Bell (1992), page 96
  174. ^ Bell (1992), page 97
  175. ^ "Al-Kindi biography". www-gap.dcs.st-and.ac.uk. Archived from the original on 26 October 2007.
  176. ^ a b "Bhaskaracharya II". Students' Encyclopedia India (2000). (Volume 1: Adb Allah ibn al Abbas – Cypress). p. 200. ISBN 0-85229-760-2
  177. ^ Kumar (2004), page 23
  178. ^ Singh, Manpal (2005), page 385
  179. ^ Plofker (2007), page 474
  180. ^ a b c Goonatilake (1998), page 127 – 128
  181. ^ Baber (1996), page 34
  182. ^ Rao K. A. (2000), page 252
  183. ^ Pingree (2003):

    "Geometry, and its branch trigonometry, was the mathematics Indian astronomers used most frequently. In fact, the Indian astronomers in the third or fourth century, using a pre-Ptolemaic Greek table of chords, produced tables of sines and versines, from which it was trivial to derive cosines. This new system of trigonometry, produced in India, was transmitted to the Arabs in the late eighth century and by them, in an expanded form, to the Latin West and the Byzantine East in the twelfth century."

  184. ^ J. J. O'Connor and E.F. Robertson (1996). Trigonometric functions Archived 20 January 2013 at the Wayback Machine. MacTutor History of Mathematics Archive
  185. ^ a b "Varahamihira biography". www-history.mcs.st-andrews.ac.uk. Retrieved 13 April 2015.
  186. ^ J. J. O'Connor and E. F. Robertson (2000). Paramesvara, MacTutor History of Mathematics archive.
  187. ^ a b Goonatilake (1998), page 37
  188. ^ Amma (1999), pp. 182–183
  189. ^ a b Roy (1990)
  190. ^ Borwein (2004), page 107
  191. ^ Plofker (2007), page 481
  192. ^ Bressoud (2002)
  193. ^ Plofker (2001)
  194. ^ Katz (1995)
  195. ^ Stillwell 2004, p. 173.
  196. ^ Van Brummelen, Glen (2009). The mathematics of the heavens and the earth: the early history of trigonometry. Princeton University Press. p. 329. ISBN 9780691129730. (p.111)
  197. ^ Meijering, Erik (March 2002). "A Chronology of Interpolation From Ancient Astronomy to Modern Signal and Image Processing". Proceedings of the IEEE. 90 (3): 319–342. doi:10.1109/5.993400.
  198. ^ Gupta, R. C. "Second-order interpolation in Indian mathematics upto the fifteenth century". Indian Journal of History of Science. 4 (1 & 2): 86–98. Reprinted as: Ramasubramanian, K. (2019). "Second-Order Interpolation in Indian Mathematics up to the Fifteenth Century". Gaṇitānanda. pp. 263–276. doi:10.1007/978-981-13-1229-8_27. ISBN 978-981-13-1228-1.
  199. ^ Knuth 2005, pp. 1–26.
  200. ^ Plofker (2007), pp. 419–436
  201. ^ Joseph (2000), page 306
  202. ^ Kala Fischbein, Tammy Brooks. "Brahmagupta's Formula". University of Georgia. Retrieved 3 November 2011.
  203. ^ Weisstein, Eric W. "Brahmagupta Matrix". Mathworld. Retrieved 3 November 2011.
  204. ^ "India". Archived from the original on 14 November 2007. Retrieved 5 March 2008.
  205. ^ Hall, Rachel (16 February 2005). "Math for Poets and Drummers-The Mathematics of Meter" (PDF). Archived from the original (PDF) on 7 September 2008. Retrieved 5 March 2008. {{cite journal}}: Cite journal requires |journal= (help)
  206. ^ Kulkarni, Amba (2007). Recursion and Combinatorial Mathematics in Chandashaastra (Preprint). arXiv:math/0703658. Bibcode:2007math......3658K.
  207. ^ Datta, Bibhutibhusan; Singh, Awadhesh Narayan (2019). "Use of permutations and combinations in India". In Kolachana, Aditya; Mahesh, K.; Ramasubramanian, K. (eds.). Studies in Indian Mathematics and Astronomy: Selected Articles of Kripa Shankar Shukla. Sources and Studies in the History of Mathematics and Physical Sciences. Springer Singapore. pp. 356–376. doi:10.1007/978-981-13-7326-8_18. ISBN 978-981-13-7325-1. S2CID 191141516.. Revised by K. S. Shukla from a paper in Indian Journal of History of Science 27 (3): 231–249, 1992, MR1189487. See p. 363.
  208. ^ Goonatilake, S. (1998). Toward a Global Science: Mining Civilizational Knowledge. Indiana University Press. p. 126. ISBN 9780253333889. Retrieved 13 April 2015.
  209. ^ Edwards, A.W.F. (2002). Pascal's Arithmetical Triangle: The Story of a Mathematical Idea. Johns Hopkins University Press. p. 201. ISBN 9780801869464. Retrieved 13 April 2015.
  210. ^ Puttaswamy (2000), page 416
  211. ^ Stillwell 2004, pp. 72–73.
  212. ^ Stillwell (2004), pages 72–73
  213. ^ Joseph, G. G. (2011), The Crest of the Peacock: Non-European Roots of Mathematics (3rd ed.), Princeton University Press, p. 352.
  214. ^ See, e.g., Shparlinski, Igor (2013), Cryptographic Applications of Analytic Number Theory: Complexity Lower Bounds and Pseudorandomness, Progress in Computer Science and Applied Logic, vol. 22, Birkhäuser, p. 35, ISBN 978-3-0348-8037-4.
  215. ^ D. E. Knuth (1998). The Art of Computer Programming Volume 2. Pearson Education India, 1998. p. 342. ISBN 9788177583359.
  216. ^ Cooke, Roger (1997). "The Mathematics of the Hindus". The History of Mathematics: A Brief Course. Wiley-Interscience. pp. 213–215. ISBN 0-471-18082-3.
  217. ^ "Panini biography". www-history.mcs.st-andrews.ac.uk.
  218. ^ Ingerman, P. Z. (1967). ""Pāṇini Backus Form" suggested". Communications of the ACM. 10 (3): 137. doi:10.1145/363162.363165. S2CID 52817672.
  219. ^ a b c d e Dickinson, pages 1–3
  220. ^ Hershey (2004), page 22
  221. ^ Malkin (1996), page 12
  222. ^ Hershey (2004), pages 3 & 23
  223. ^ Thomas (2007), page 46
  224. ^ Read (2005), page 17
  225. ^ a b Lee, page 685
  226. ^ a b Wenk, pages 535–539
  227. ^ MSN Encarta (2007). Diamond. 1 November 2009.
  228. ^ "Zinc-Fact sheet". Australian mines. Archived from the original on 7 November 2011. Retrieved 4 November 2011.
  229. ^ Srinivasan, Ranganathan. "Mettalurgical heritage of India". Christian-Albrechts-University of Kiel. Retrieved 4 November 2011.
  230. ^ Rina Shrivastva (1999). "Smelting furnaces in Ancient India" (PDF). Indian Journal of History & Science,34(1), Digital Library of India. Archived from the original (PDF) on 25 April 2012. Retrieved 4 November 2011.
  231. ^ a b Craddock (1983)
  232. ^ Biswas (1986), page 11
  233. ^ White, M.J. "Sidereal, tropical, and anomalistic years" (PDF). Retrieved 16 May 2016.
  234. ^ Neugebauer, O. (1975). A History Of Ancient Mathematical Astronomy, Vol 1. Springer-Verlag. pp. 293, 294.
  235. ^ Pickover, Clifford (16 April 2008). Archimedes to Hawking: Laws of Science and the Great Minds Behind Them. Oxford University Press. ISBN 9780199792689.
  236. ^ Bose, Mainak Kumar (1988). Late classical India. A. Mukherjee & Co.
  237. ^ *Sen, Amartya (2005). The Argumentative Indian. Allen Lane. p. 29. ISBN 978-0-7139-9687-6.
  238. ^ Kelley, David H.; Milone, Eugene F. (2011). Exploring Ancient Skies: A Survey of Ancient and Cultural Astronomy. Springer. p. 293. ISBN 9781441976246.
  239. ^ Ramasubramanian, K.; Srinivas, M. D.; Sriram, M. S. (1994). "Modification of the earlier Indian planetary theory by the Kerala astronomers (c. 1500 AD) and the implied heliocentric picture of planetary motion". Current Science. 66 (10): 784–790. JSTOR 24098820.
  240. ^ Joseph 2000, p. 408.
  241. ^ B., E. (1960). "Review of The Contributions of Kerala to Sanskrit Literature". Journal of the American Oriental Society. 80 (4): 392. doi:10.2307/595925. JSTOR 595925.
  242. ^ Edwards, Graham and Sue. The Language of Drink, Alan Sutton Publishing, 1988.
  243. ^ Razpush, Shahnaz (15 December 2000). "ḠALYĀN". Encyclopedia Iranica. pp. 261–265. Retrieved 19 December 2012.
  244. ^ Sivaramakrishnan, V. M. (2001). Tobacco and Areca Nut. Hyderabad: Orient Blackswan. pp. 4–5. ISBN 81-250-2013-6.
  245. ^ Blechynden, Kathleen (1905). Calcutta, Past and Present. Los Angeles: University of California. p. 215.
  246. ^ Rousselet, Louis (1875). India and Its Native Princes: Travels in Central India and in the Presidencies of Bombay and Bengal. London: Chapman and Hall. p. 290. ISBN 9788120618879.
  247. ^ Mallapaty, Smriti (28 March 2024). "Cutting-edge CAR-T cancer therapy is now made in India — at one-tenth the cost". Nature. 627 (8005): 709–710. Bibcode:2024Natur.627..709M. doi:10.1038/d41586-024-00809-y. PMID 38514877.
  248. ^ Brahmachari, U. N. (April 1922). "A New Form of Cutaneous Leishmaniasis—Dermal Leishmanoid". The Indian Medical Gazette. 57 (4): 125–127. PMC 5186533. PMID 29008368.
  249. ^ De, S. N.; Sarkar, J. K.; Tribedi, B. P. (1951). "An experimental study of the action of cholera toxin". The Journal of Pathology and Bacteriology. 63 (4): 707–717. doi:10.1002/path.1700630417. PMID 14898376.
  250. ^ Jayaraman KS (19 October 1978). "India reveals deep-frozen test-tube baby". New Scientist. p. 159. Retrieved 4 September 2021.
  251. ^ "Test tube triumph & tragedy – Nobel for UK scientist stirs memory of a Bengal doctor". The Telegraph. 5 October 2010. Retrieved 22 May 2012.
  252. ^ Test Tube Baby. YouTube. Educational Multimedia Research Centre, Kolkata. 23 August 2013. Retrieved 4 September 2021.
  253. ^ Goulding E, Lim B (August 2014). "McDonald transvaginal cervical cerclage since 1957: from its roots in Australia into worldwide contemporary practice". BJOG. 121 (9): 1107. doi:10.1111/1471-0528.12874. PMID 25047486. S2CID 21004646.
  254. ^ Rodriguez, Vincente (2010). "A brief history of horns". In Compliance Magazine. Same Page Publishing. Retrieved 12 November 2010.
  255. ^ Emerson, D.T. (1997). "The work of Jagadis Chandra Bose: 100 years of mm-wave research". 1997 IEEE MTT-S International Microwave Symposium Digest. Vol. 2. pp. 553–556. doi:10.1109/MWSYM.1997.602853. ISBN 0-7803-3814-6.
  256. ^ "Famous Scientists – Jagdish Chandra Bose". humantouchofchemistry.com. Archived from the original on 18 November 2015. Retrieved 5 January 2016.
  257. ^ "15 Indian Inventions & Discoveries That Shaped the Modern World – Part 2". HuffPost.
  258. ^ "Telecom carriers may enhance coverage once 5Gi, 5G standards merge: NG Subramaniam - ET Telecom".
  259. ^ Emerson, D.T. (1997). "The work of Jagadis Chandra Bose: 100 years of mm-wave research". 1997 IEEE MTT-S International Microwave Symposium Digest. Vol. 2. pp. 553–556. doi:10.1109/MWSYM.1997.602853. ISBN 0-7803-3814-6.
  260. ^ https://patents.google.com/patent/WO2008004248A1/en
  261. ^ https://dl.acm.org/doi/10.5555/645465.653819
  262. ^ https://timesofindia.indiatimes.com/city/bengaluru/autolay-software-makes-ada-a-global-leader/articleshow/1478879143.cms
  263. ^ S Prasanna, Microsoft's VJ#.Net is made in India Archived 28 November 2013 at the Wayback Machine, Express Computer, 29 July 2002 – invalid link !
  264. ^ "The Hindu Business Line : Microsoft lines up big plans for Hyderabad centre". thehindubusinessline.com.
  265. ^ "Not just "IT coolies": An Indian computer scientist built a new programming language in Bengaluru". 20 April 2017.
  266. ^ "Kojo home page". Retrieved 29 August 2012.
  267. ^ Geertjan Wielenga (19 February 2010). "Interview: Scala Learning Environment on the NetBeans Platform". DZone. Retrieved 29 August 2012.
  268. ^ "India's home-grown microprocessor Shakti is now part of tech-giant Altair's offerings". 7 July 2021.
  269. ^ Aufranc (CNXSoft), Jean-Luc (4 February 2022). "India goes RISC-V with VEGA processors – CNX Software". CNX Software – Embedded Systems News. Retrieved 13 July 2022.
  270. ^ "FTP Is Almost 50 Years Old—and It's Ready to Retire". www.vice.com. 29 September 2020. Retrieved 10 August 2022.
  271. ^ https://www.livemint.com/companies/news/coal-india-and-nhpc-join-forces-to-convert-abandoned-mines-into-pump-storage-projects-boosting-energy-transition-11695059193255.html [bare URL]
  272. ^ "MSN". MSN.
  273. ^ "Paving new paths for sustainable construction".
  274. ^ "Chenab Rail Bridge Achieves Big Milestone! Indian Railways Conducts Train Trials on World's Highest Railway Bridge - Check Top Facts". The Times of India. 20 June 2024.
  275. ^ "Engineers develop new tunnelling method for Kashmir rail link project - ET Infra".
  276. ^ "Engineers develop new tunnelling method for Kashmir rail link project". The Times of India. 22 October 2023.
  277. ^ "Engineers Develop Himalayan Tunnelling Method for Katra-Banihal Section of the Kashmir rail Link Project". 23 October 2023.
  278. ^ "Zydex Industries develops nanotechnology solution for durable roads". 18 January 2023.
  279. ^ "Potholes to become history with smooth ride; breakthrough by Zydex - Construction Week India". 19 January 2023.
  280. ^ Deloney, Matthew L. (30 December 2021). "What Are Plastic Roads | How to Make Plastic Roads | Who Invented Plastic Roads | First Man Made Plastic Road | Advantages & Disadvantages of Plastic Roads". CivilJungle. Retrieved 25 July 2022.
  281. ^ "This Indian Genius Created Roads With Plastic Waste, Now Entire World Uses His Technique". IndiaTimes. 9 February 2020. Retrieved 25 July 2022.
  282. ^ Lee, Chermaine. "Could plastic roads make for a smoother ride?". www.bbc.com. Retrieved 25 July 2022.
  283. ^ Ghosh, Sahana (22 April 2024). "Meet Vasuki indicus, among the longest snakes that ever lived". Nature India. doi:10.1038/d44151-024-00048-0.
  284. ^ "IIT scientist unearth ancient Indian dinosaur; here's what they discovered about the earliest dinosaur, Tharosaurus Indicus". The Economic Times. 8 August 2023.
  285. ^ "CSIR Milestones | Council of Scientific & Industrial Research".
  286. ^ Van Vuren, Petrus Jansen; McAuley, Alexander J.; Kuiper, Michael J.; Singanallur, Nagendrakumar B.; Bruce, Matthew P.; Riddell, Shane; Goldie, Sarah; Mangalaganesh, Shruthi; Chahal, Simran; Drew, Trevor W.; Blasdell, Kim R.; Tachedjian, Mary; Caly, Leon; Druce, Julian D.; Ahmed, Shahbaz; Khan, Mohammad Suhail; Malladi, Sameer Kumar; Singh, Randhir; Pandey, Suman; Varadarajan, Raghavan; Vasan, Seshadri S. (2022). "Petrus Jansen van Vuren, et al (2022)". Viruses. 14 (4): 800. doi:10.3390/v14040800. PMC 9031315. PMID 35458530.
  287. ^ Mallapaty, Smriti (9 September 2021). "India's DNA COVID vaccine is a world first – more are coming". Nature. 597 (7875): 161–162. Bibcode:2021Natur.597..161M. doi:10.1038/d41586-021-02385-x. PMID 34475553. S2CID 237401121.
  288. ^ https://www.tribuneindia.com/news/chandigarh/mohali-institute-develops-reactor-for-cost-effective-production-of-hydrogen-using-sunlight-water-318138 [bare URL]
  289. ^ "Large-scale reactor developed for cost-effective production of hydrogen using sunlight and water | Department of Science & Technology".
  290. ^ "First of Its Kind! Central Government Inaugurates India's 'Coal to Methanol' Plant Made by BHEL". 17 January 2022.
  291. ^ https://timesofindia.indiatimes.com/business/india-business/jindal-shl-to-make-high-nitrogen-steel-for-defence-sector/articleshow/57408503.cms#:~:text=With%20this%2C%20JSHL%20claims%20to%20be%20India's,commercially%20manufacture%20HNS%20for%20the%20Defence%20sector.
  292. ^ Correspondent, Our (21 November 2002). "Bhel develops device to reduce T&D losses". The Times of India – via Press Trust of India. {{cite news}}: |last= has generic name (help)
  293. ^ Correspondent, HT (7 October 2006). "The first-of-its-kind Controlled Shunt Reactor (CSR) has been developed by BHEL in-house, said a BHEL release. The device, which operates automatically, depending on system requirement in less than 10 milliseconds, improves power transfer capability of transmission lines". The Hindustan Times – via HT Correspondent, Bhopal. {{cite news}}: |last= has generic name (help)
  294. ^ "Development of Nickel-Base Superalloy & Components for Aeroengine Applications | Indian Aerospace and Defence Bulletin - News for aerospace and defence in India". 23 February 2022.
  295. ^ https://papers.ssrn.com/sol3/papers.cfm?abstract_id=4902841
  296. ^ "High strain rate behavior of GTM-900 titanium alloy - CSIR - NAL".
  297. ^ https://nopr.niscpr.res.in/bitstream/123456789/20553/1/IJEMS%209(5)%20351-358.pdf
  298. ^ "High Temperature Titanium Alloys & Components | Defence Research and Development Organisation - DRDO, Ministry of Defence, Government of India".
  299. ^ https://www.inae.in/wp-content/themes/fortuna-child/img/Metallurgy%20REPORT.pdf
  300. ^ https://www.ias.ac.in/article/fulltext/boms/017/06/0733-0745
  301. ^ "India's Deep Sea Mining Endeavours: A Search for Climate Solutions in Deep Waters | Manohar Parrikar Institute for Defence Studies and Analyses".
  302. ^ https://drs.nio.res.in/drs/bitstream/handle/2264/754/Refresher_Course_Mar_Geol_Geophys_2007_Lecture_Notes_52.pdf;jsessionid=CE99C6BA341E8AE14A9E5076EDED73A4?sequence=2
  303. ^ "Indian Scientists Produce Clean H2 with Carbon Capture Efficiency of 99.58% - Mercom India".
  304. ^ Ramappa, K. B.; Jadhav, Vilas; Manjunatha, A. V. (2022). "A benchmark study on economic impact of Neem Coated Urea on Indian agriculture". Scientific Reports. 12 (1): 9082. Bibcode:2022NatSR..12.9082R. doi:10.1038/s41598-022-12708-1. PMC 9156691. PMID 35641568.
  305. ^ "New Technological Developments in Electric Traction".
  306. ^ "In action: The world's first fully commercial carbon capture and utilisation plant - edie".
  307. ^ "Technology Helps Indian Factory Convert Carbon Emissions". 6 January 2017.
  308. ^ "RDSO triple stack container trials on WDFC_DFCCIL". YouTube. 10 March 2022.
  309. ^ "Trials to reduce per-unit logistics cost by Indian Railways". YouTube. 17 October 2023.
  310. ^ "Innovative logistics: Stacking small containers for optimised loading".
  311. ^ "Jagadis Bose Research on Measurement of Plant Growth". Retrieved 5 August 2008.
  312. ^ Geddes, pages 173–176
  313. ^ "Definition of Murty interferometer". Photonics.com.
  314. ^ Riley, M. E.; Gusinow, M. A. (1 October 1977). "Laser beam divergence utilizing a lateral shearing interferometer". Applied Optics. 16 (10): 2753–6. Bibcode:1977ApOpt..16.2753R. doi:10.1364/AO.16.002753. PMID 20174226.
  315. ^ "ISRO conducts flight experiment of Air Breathing Propulsion System".
  316. ^ "Isro successfully conducts second test of Air Breathing Propulsion Technology". 23 July 2024.
  317. ^ "ISRO conducts experimental flight of air-breathing propulsion system". The Hindu. 23 July 2024.
  318. ^ Karthikeyan, Suchitra (22 May 2023). "Explained | What is a Reusable Launch Vehicle? Who is using it now? How far along is India?". The Hindu.
  319. ^ "Space to learn: The Hindu Editorial on the failure of ISRO's maiden small satellite launch vehicle mission". The Hindu. 9 August 2022.
  320. ^ "Indian scientists make breakthrough discovery of material that repairs itself". 24 July 2021.
  321. ^ "What's India's New Explosive SEBEX 2 That Will Improve Lethality of Warheads? Military Tech Explained". 2 July 2024.
  322. ^ https://www.isro.gov.in/media_isro/pdf/capacitybuilding/ISROIPRApril2024.pdf
  323. ^ https://www.vssc.gov.in/SilicaFibres.html
  324. ^ https://allindianpatents.com/patents/253851-high-purity-porous-silica-fiber-silica-matrix-composite-and-a-method-of-manufacturing-thereof.html
  325. ^ "This Material Can Convert Infrared Light to Renewable Energy". 11 July 2022.
  326. ^ "Groundbreaking! Indian Researchers Discover Material Which Turns Infrared Light into Renewable Energy". 10 July 2022.
  327. ^ "IISER Bhopal breakthrough to produce high-intensity lasers". The Times of India. 10 March 2023.
  328. ^ Saji, N. H.; Goswami, B. N.; Vinayachandran, P. N.; Yamagata, T. (23 September 1999). "A dipole mode in the tropical Indian Ocean". Nature. 401 (6751): 360–363. Bibcode:1999Natur.401..360S. doi:10.1038/43854. PMID 16862108. S2CID 4427627.
  329. ^ Prasad, R. (10 August 2019). "IIT Madras registers initial success with iron ion battery". The Hindu.
  330. ^ https://ipc.iisc.ac.in/includes/kcpbook/SCS-Part-I.pdf [bare URL PDF]
  331. ^ Nawlakhe, W. G.; Paramasivam, R. (1993). "Defluoridation of potable water by Nalgonda technique". Current Science. 65 (10): 743–748. JSTOR 24095996.
  332. ^ https://wedc-knowledge.lboro.ac.uk/resources/conference/22/dahi.pdf
  333. ^ "Bounce ties up with deep-tech start-up Chara for local production of EV motors". The Economic Times. 10 August 2021.
  334. ^ "An electric motor from Bengaluru can break China's rare earth mineral hegemony".
  335. ^ "MD-15: The New Fuel that May Replace Diesel in Indian Railways' Locomotives, Save Rs 2,280 Crore". 3 November 2023.
  336. ^ "IOC: Facility for blended fuel to come up in Chennai". The Times of India. 28 April 2023.
  337. ^ "CBDC-R users to hit 50,000 by Jan-end on better acceptance". 9 January 2023.
  338. ^ "Can ATAGS Give India's Military a Much-needed Boost? The Answer is Yes".
  339. ^ "Milipol Paris 2023: MKU unveils 'first-of-its-kind' rifle-rated ballistic helmet - European Security & Defence". 16 November 2023.
  340. ^ "'India developing E-bomb to paralyze networks'". The Times of India. 29 August 2013.
  341. ^ "LAKSHYA-2 | Defence Research and Development Organisation - DRDO, Ministry of Defence, Government of India".
  342. ^ "Air independent propulsion system for submarines based on phosphoric acid fuel cell with onboard hydrogen generator".
  343. ^ "AC Helmet: What is it and how is it different from a riding helmet". The Times of India. 22 August 2023.
  344. ^ "CNG Delhi – the world's cleanest public bus system running on CNG".
  345. ^ Crandall & Pomerance (2005), pages 200–201
  346. ^ a b Weisstein, Eric W. "AKS Primality Test". MathWorld.
  347. ^ Crandall & Papadopoulos (2003), page 2
  348. ^ Nitis (2000), page 325
  349. ^ Boos & Oliver (1998)
  350. ^ Raju, C.K. (2009), "Kosambi the Mathematician", Economic and Political Weekly, 44 (20): 33–45
  351. ^ Kosambi, D. D. (1943), "Statistics in Function Space", Journal of the Indian Mathematical Society, 7: 76–88, MR 0009816.
  352. ^ Berndt & Rankin (2001)
  353. ^ a b c d "Acharya Prafulla Chandra Ray" Archived 27 September 2007 at the Wayback Machine, Viyan Prasar, Department of Science and Technology, Government of India.
  354. ^ a b Shanti Swarup Bhatnagar Archived 18 October 2013 at the Wayback Machine. Vigyan Prasar: Government of India.
  355. ^ a b Penney (1967), page 39
  356. ^ a b c Rigden (2005), pages 143–144
  357. ^ a b c Fraser (2006), page 238
  358. ^ Dauxois & Peyrard (2006), pages 297–298
  359. ^ Chakraborti, P.C.; Mitra, M.K. (September 2007). "Microstructure and tensile properties of high strength duplex ferrite–martensite (DFM) steels". Materials Science and Engineering: A. 466 (1–2): 123–133. doi:10.1016/j.msea.2007.02.042.
  360. ^ a b "Indian Scientists" (November 2004), Science Popularisation and Public Outreach Committee, Tata Institute of Fundamental Research.
  361. ^ Sarkar (2006), page 94
  362. ^ Taguchi & Jugulum (2002), pages 6–7
  363. ^ Ramakrishnan (2001)
  364. ^ "Raman effect".Encyclopædia Britannica (2008)
  365. ^ Naresh (2005)
  366. ^ Shadab,K. A. (2020). "PERIODICITY IN NUCLEAR PROPERTIES". International Research Journal of Natural and Applied Sciences. 7 (5): 18–61.
  367. ^ Awakening Indians to India. All India Chinmaya Yuva Kendra (1st ed.). Mumbai, India: Central Chinmaya Mission Trust. 2003. ISBN 81-7597-175-4. OCLC 296288988.{{cite book}}: CS1 maint: others (link)[page needed]
  368. ^ Staff Reporter (25 September 2009). "MIP detected water on Moon way back in June: ISRO Chairman". The Hindu.
  369. ^ "Did India beat NASA to find water on moon?". m.ndtv.com. Archived from the original on 30 November 2016. Retrieved 29 November 2016.
  370. ^ "Chandrayaan-1 | Indian space probe". Encyclopædia Britannica.
  371. ^ "Chandrayaan first discovered water on moon, but… | Latest News & Updates at Daily News & Analysis". dna. 25 September 2009.
  372. ^ Narlikar (2002), page 188
  373. ^ Vishveshwara, C.V., Nature, 1970, 227, 936

Bibliography

edit
edit