Explanation: Historical consensus places Aryabhata I's lifespan between 476 CE and 550 CE, firmly within the 5th and 6th centuries CE.

Explanation: Scholarly consensus identifies Aryabhata's birthplace as Kusumapura, commonly equated with Pataliputra (near modern Patna), not Delhi.

Explanation: Aryabhata's most renowned surviving work is the *Aryabhatiya*. The *Arya-siddhanta* is known only through references by later scholars and is considered lost.

Explanation: The common misspelling of Aryabhata's name as 'Aryabhatta' stems from an analogy with other Sanskrit names bearing the suffix '-bhatta'. However, authoritative astronomical texts, including those by Brahmagupta, consistently record his name as 'Aryabhata'.

Explanation: The lost work *Arya-siddhanta* is known through later references to have included detailed descriptions of astronomical instruments such as the gnomon (*shanku-yantra*), shadow instruments, angle-measuring devices, and water clocks.

Explanation: The *Aryabhatiya* comprises 108 main verses, supplemented by 13 introductory verses. While often referred to as *Arya-shatas-ashta* ('Aryabhata's 108'), the total verse count is slightly higher than 108.

Explanation: Aryabhata I was a preeminent mathematician and astronomer of the classical period of Indian science, renowned for his foundational contributions to both fields.

Explanation: Aryabhata I lived during the period spanning 476 CE to 550 CE, a significant era for intellectual development in India.

Explanation: Scholars generally identify Aryabhata's birthplace as Kusumapura, which is widely accepted to be Pataliputra, located in the vicinity of modern-day Patna.

Explanation: Aryabhata's most celebrated and extant work is the treatise known as the *Aryabhatiya*.

Explanation: The common misspelling of Aryabhata's name as 'Aryabhatta' arises from an analogy with other Sanskrit names ending in the suffix '-bhatta'. However, authoritative astronomical texts, including those by Brahmagupta, consistently use the spelling 'Aryabhata'.

Explanation: The lost treatise *Arya-siddhanta* contained descriptions of various astronomical instruments, notably including the gnomon, known in Sanskrit as *shanku-yantra*.

Explanation: The *Aryabhatiya* is sometimes known as *Arya-shatas-ashta* because it comprises 108 main verses, in addition to introductory verses, translating to 'Aryabhata's 108'.

Explanation: Aryabhata developed the *kuttaka* method, a recursive algorithm for solving indeterminate equations, particularly first-order Diophantine equations.

Explanation: The foundational nature of Aryabhata's *kuttaka* method for solving indeterminate equations was such that the field of algebra itself was sometimes referred to as *kuttaka-ganita*, underscoring its significance in the history of mathematics.

Explanation: Aryabhata developed the *kuttaka* method, a technique for solving indeterminate equations (specifically first-order Diophantine equations), characterized by its recursive algorithm that systematically reduces problems into smaller numerical components.

Explanation: Aryabhata provided explicit formulas for calculating the sum of the first 'n' squares (∑k²) and the sum of the first 'n' cubes (∑k³).

Explanation: The *kuttaka* method is historically significant in algebra because it provided a sophisticated recursive algorithm for solving indeterminate equations, becoming a standard technique in Indian mathematics.

Explanation: Due to the foundational importance of his *kuttaka* method for indeterminate equations, Aryabhata's contributions led to the field of algebra sometimes being referred to as *kuttaka-ganita*.

Explanation: Aryabhata made seminal contributions to trigonometry by introducing the concepts of *jya* (sine) and *kojya* (cosine) and by constructing detailed sine tables. These advancements were critical for astronomical calculations and profoundly influenced the subsequent development of trigonometry.

Explanation: Aryabhata calculated the value of pi (π) to be 3.1416, achieving an accuracy of four decimal places, which was exceptionally precise for his era.

Explanation: Aryabhata employed the term *ardha-jya* (half-chord) for the sine function. The term for the cosine function in his work was *kojya*.

Explanation: Aryabhata introduced the term *kojya*, which is the Sanskrit precursor to the modern trigonometric function known as cosine.

Explanation: The term *jya*, derived from *ardha-jya* (half-chord) used by Aryabhata, is the direct linguistic ancestor of the modern term 'sine', having evolved through Arabic and Latin translations.

Explanation: Aryabhata's development of sine tables and the introduction of concepts like *jya* (sine) and *kojya* (cosine) represent foundational contributions to the field of trigonometry.

Explanation: Aryabhata calculated the value of pi (π) to be 3.1416, achieving an accuracy of four decimal places, which was exceptionally precise for his era.

Explanation: The term 'sine' evolved from Aryabhata's *ardha-jya* (half-chord) through several stages: it was abbreviated to *jya*, translated into Arabic as *jiba*, then erroneously interpreted as *jaib* ('pocket'), and finally rendered into Latin as *sinus*, the direct etymological root of 'sine'.

Explanation: Aryabhata used the term *jya*, derived from *ardha-jya* (half-chord), for the sine function, a term that underwent linguistic evolution to become the modern word 'sine'.

Explanation: The term *utkrama-jya*, employed by Aryabhata, corresponds to the versine, a trigonometric function mathematically defined as 1 minus the cosine of an angle.

Explanation: Aryabhata's use of the term *asanna* ('approaching') in conjunction with his precise calculation of pi suggests an understanding that pi is an irrational number, a concept not formally proven in European mathematics until centuries later.

Explanation: Aryabhata articulated a sophisticated understanding of the relativity of motion, notably by analogizing the apparent celestial movement to the visual perception of stationary objects receding from a moving vessel.

Explanation: Contrary to this assertion, Aryabhata proposed that the Earth itself rotates daily on its axis, which accounts for the apparent daily motion of the celestial sphere.

Explanation: Aryabhata's astronomical model was fundamentally geocentric, positing the Earth as the central body around which other celestial objects revolved, albeit with complex epicycles to account for observed motions.

Explanation: Aryabhata's calculation of the Earth's sidereal rotation period, approximately 23 hours, 56 minutes, and 4.1 seconds, was remarkably precise and closely aligns with modern accepted values.

Explanation: Aryabhata posited that the Moon and planets are luminous due to the reflection of sunlight, a scientifically accurate assertion for his time.

Explanation: This analogy illustrates Aryabhata's profound grasp of the concept of the relativity of motion, wherein perceived motion depends on the observer's frame of reference.

Explanation: Aryabhata's proposal asserted that the Earth is spherical and rotates daily upon its axis, thereby accounting for the apparent motion of the stars.

Explanation: Aryabhata's model is characterized as geocentric, with the Earth at the center, utilizing epicycles to explain the complex motions of the Sun, Moon, and planets.

Explanation: Aryabhata's calculation of the Earth's sidereal rotation period differed from the modern accepted value by less than a tenth of a second.

Explanation: Aryabhata proposed that the Moon and planets are luminous not through intrinsic generation of light, but by reflecting sunlight.

Explanation: Aryabhata's *Aryabhatiya* explicitly stated that the Earth is round, a significant contribution to the understanding of celestial mechanics and geography.

Explanation: In Aryabhata's geocentric model, the sequence of celestial bodies ordered from Earth was: Moon, Mercury, Venus, Sun, Mars, Jupiter, Saturn, followed by the fixed stars (asterisms).

Explanation: Aryabhata provided a rational, scientific explanation for eclipses, attributing them to the Earth's shadow falling on the Moon and the Moon's shadow falling on the Earth, thereby refuting prevailing mythological interpretations.

Explanation: Aryabhata calculated the sidereal year to be 365 days, 6 hours, 12 minutes, and 30 seconds. This value is highly accurate, differing from the modern value by only approximately 3 minutes and 20 seconds.

Explanation: While Aryabhata's model was geocentric, some scholarly interpretations suggest he may have alluded to elliptical planetary orbits, rather than definitively proving circular ones.

Explanation: The *shighra* anomaly, which addresses the accelerated apparent motion of certain planets relative to the Sun's mean velocity, has prompted scholarly speculation that Aryabhata's calculations may have been informed by heliocentric principles, despite his presented model being geocentric.

Explanation: Aryabhata's reference to 'Lanka' signifies an abstract point situated on the Earth's equator, serving as a reference meridian for his astronomical calculations, rather than a specific geographical location.

Explanation: In Aryabhata's geocentric model, *manda* denotes the smaller, slower epicycle, while *shighra* denotes the larger, faster epicycle, both employed to account for the observed complexities in planetary motion.

Explanation: Aryabhata explained solar and lunar eclipses as phenomena caused by shadows: lunar eclipses occur when the Moon enters the Earth's shadow, and solar eclipses occur when the Moon casts its shadow upon the Earth.

Explanation: Aryabhata's calculation of the sidereal year differed from the modern value by approximately 3 minutes and 20 seconds, demonstrating remarkable precision.

Explanation: The *shighra* anomaly refers to the observed faster apparent motion of certain planets relative to the Sun's mean speed, a phenomenon accounted for in Aryabhata's model.

Explanation: Aryabhata's reference to 'Lanka' denotes an abstract point situated on the Earth's equator, serving as a prime meridian for his astronomical calculations, rather than a specific geographical location.

Explanation: While Aryabhata's works significantly influenced Islamic scholars, direct translation into Latin and direct influence on early European astronomers is not documented. His ideas reached Europe primarily through Arabic translations and commentaries.

Explanation: The 'Tables of Toledo' were not directly authored by Aryabhata but were based on the astronomical work of Al-Zarqali, which incorporated methodologies derived from Aryabhata's system, thus representing an indirect influence.

Explanation: Scholars in the Islamic world were significantly influenced by the Arabic translations of Aryabhata's works, integrating his mathematical and astronomical concepts into their own scholarship.

Explanation: The *Jalali calendar*, established centuries after Aryabhata, drew upon his sophisticated calendric calculations, particularly his methods for accurately tracking solar transits and seasonal changes.

Explanation: Numerous institutions and entities are named in honor of Aryabhata, including the Aryabhatta Research Institute of Observational Sciences (ARIES), Aryabhatta Knowledge University, and Aryabhata, India's inaugural satellite.

Explanation: The *Paitamahasiddhanta*, predating Aryabhata's known works, features a geocentric model employing epicycles, similar to Aryabhata's system, suggesting a common intellectual heritage or mutual influence in astronomical thought.

Explanation: The *Aryabhatiya* is a seminal work that integrates both mathematical and astronomical concepts, covering topics such as celestial sphere geometry, planetary positions, and the causes of day and night alongside arithmetic and algebra.

Explanation: The *Gitikapada* chapter of the *Aryabhatiya* is primarily concerned with large units of time and cosmological frameworks, including concepts like *kalpa*, *manvantra*, and *yuga*, and also contains a table of sines.

Explanation: The *Golapada* chapter of the *Aryabhatiya* is dedicated to the geometry and trigonometry of the celestial sphere, addressing topics such as the ecliptic, celestial equator, Earth's shape, and the mechanisms behind diurnal and nocturnal cycles, rather than time units and planetary positions.

Explanation: The *Kalakriyapada* chapter of the *Aryabhatiya* is primarily focused on calendrical calculations, including units of time, planetary positions, and the determination of intercalary months, rather than mensuration and algebraic equations.

Explanation: The *Aryabhatiya* covers a wide range of topics in mathematics and astronomy, including algebra, mensuration, and the causes of day and night. However, it predates the development of modern physics and therefore does not address its principles.

Explanation: The *Gitikapada* chapter of the *Aryabhatiya* addresses vast temporal units, including the *kalpa*, *manvantra*, and *yuga*, establishing a cosmological framework distinct from earlier traditions. This chapter also includes a table of sines.

Explanation: The *Golapada* chapter of the *Aryabhatiya* is dedicated to the geometry and trigonometry of the celestial sphere, encompassing topics such as the ecliptic, celestial equator, Earth's form, and the mechanisms behind diurnal and nocturnal cycles.

Explanation: The *Kalakriyapada* chapter of the *Aryabhatiya* is dedicated to the calculation of time units, planetary positions, and the determination of intercalary months and the structure of the week.