mapmakers in the 15th Century gradually replaced theology with knowledge of faraway places, as reported by travelling merchants like Marco Polo.
Gerhardus Mercator, the foremost shipmaker of the 16th century, developed a technique of arranging meridians and parallels in such a way that navigators could draw straight lines between two points and steer a constant compass course between them. This distortion formula, introduced on his world map of 1569, created the ‘Greenland problem’. Even on some standard maps to this day, Greenland looks as large as South Africa – one of the many problems when one tries to portray a round world on a flat sheet of paper. But the Mercator projection was so practical that it is still popular with sailors.
Scientific mapping of the land came into its own with the achievements of the Cassini family – father, son, grandson and great-grandson. In the late 17th century, the Italian-born founder, Jean-Dominique, invented a complex method of determining longitude based on observations of Jupiter’s moons. Using this technique, surveyors were able to produce an accurate map of France. The family continued to map the French countryside and his great-grandson finally published their famous Cassini map in 1793 during the French Revolution. While it may have lacked the artistic appeal of earlier maps, it was the model of a social and geographic map showing roads, rivers, canals, towns, abbeys, vineyards, lakes and even windmills. With this achievement, France became the first country to be completely mapped by scientific methods.
Mapmaking has come a long way since those days. Today’s surveyors rarely go into the field without being linked to navigation satellites. Their hand-held receivers are the most familiar of the new mapping technologies, and the satellite system, developed and still operated by the US Defense Department, is increasingly used by surveyors. Even ordinary hikers, sailors and explorers can tap into it for data telling them where they are. Simplified civilian versions of the receivers are available for a few hundred dollars and they are also the heart of electronic map displays available in some cars. Cartography is pressing on to cosmic frontiers, but its objective is, and always has been, to communicate a sense of ‘here’ in relation to ‘there’, however far away ‘there’ may be.
Selective Test for Applicants
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Instruction: Read the following Passage carefully and answer the questions that follows.
Today, the mapmaker’s vision is no longer confined to what the human eye can see. The perspective of mapmaking has shifted from the crow’s nest of the sailing vessel, mountain top and airplane to new orbital heights. Radar, which bounces microwave radio signals off a given surface to create images of its contours and textures, can penetrate jungle foliage and has produced the first maps of the mountains of the planet Venus. And a combination of sonar and radar produces charts of the seafloor, putting much of Earth on the map for the first time. “Suddenly it’s a whole different world for us, says Joel Morrison, chief of geography at the U. S. Bureau of the Census. ‘Our future as mapmakers – even ten years from now – is uncertain.
The world’s largest collection of maps resides in the basement of the Library of Congress in Washington, D. C. The collection, consisting of up to 4.6 million map sheets and 63, 000 atlases, includes magnificent bound collections of elaborate maps – the pride of the golden age of Dutch Cartography*. In the reading room scholars, wearing thin cotton gloves to protect the fragile sheets, examine ancient maps with magnifying glasses. Across the room people sit at their computer screens, studying the latest maps. With their prodigious memories, computers are able to store data about people, places and environments – the stuff of maps – and almost instantly information is displayed on the screen in the desired geographic context, and at the click of a button, a print-out of the map appears.
Measuring the spherical Earth ranks as the first major milestone in scientific cartography. This was first achieved by the Greek astronomer Eratosthenes, a scholar at the famous Alexandrian Library in Egypt in the third century BC. He calculated the Earth’s circumference as 25,200 miles, which was remarkable accurate. The longitudinal circumference is known today to be 24,860 miles.
Building on the ideas of his predecessors, the astronomer and geographer Ptolemy, working in the second century AD, spelled out a system for organizing maps according to grids of latitude and longitude. Today, parallels of latitude are often spaced at intervals of 10 to 20 degrees and meridians** at 15 degrees, and this is the basis for the width of modern time zones. Another legacy of Ptolemy’s is his advice to cartographers to create maps to scale. Distance on today’s maps is expressed as a fraction or ratio of the real distance. But mapmakers in Ptolemy’s time lacked the geographic knowledge to live up to Ptolemy’s scientific principles. Even now, when surveyors achieve accuracies down to inches and satellites can plot potential missile targets within feet, maps are not true pictures of reality.
However, just as the compass improved navigation and created demand for useful charts, so the invention of the printing press in the 15th century put maps in the hands of more people, and took their production away from monks, who had tended to illustrate theology rather than geography. Ocean-going ships launched an age of discovery, enlarging both what could and needed to be mapped, and awakened an intellectual spirit and desire for knowledge of the world.
Inspired by the rediscovered Ptolemy, whose writing had been preserved by Arabs after the sacking of the Alexandrian Library in AD 931, mapmakers in the 15th Century gradually replaced theology with knowledge of faraway places, as reported by travelling merchants like Marco Polo.
Gerhardus Mercator, the foremost shipmaker of the 16th century, developed a technique of arranging meridians and parallels in such a way that navigators could draw straight lines between two points and steer a constant compass course between them. This distortion formula, introduced on his world map of 1569, created the ‘Greenland problem’. Even on some standard maps to this day, Greenland looks as large as South Africa – one of the many problems when one tries to portray a round world on a flat sheet of paper. But the Mercator projection was so practical that it is still popular with sailors.
Scientific mapping of the land came into its own with the achievements of the Cassini family – father, son, grandson and great-grandson. In the late 17th century, the Italian-born founder, Jean-Dominique, invented a complex method of determining longitude based on observations of Jupiter’s moons. Using this technique, surveyors were able to produce an accurate map of France. The family continued to map the French countryside and his great-grandson finally published their famous Cassini map in 1793 during the French Revolution. While it may have lacked the artistic appeal of earlier maps, it was the model of a social and geographic map showing roads, rivers, canals, towns, abbeys, vineyards, lakes and even windmills. With this achievement, France became the first country to be completely mapped by scientific methods.
Mapmaking has come a long way since those days. Today’s surveyors rarely go into the field without being linked to navigation satellites. Their hand-held receivers are the most familiar of the new mapping technologies, and the satellite system, developed and still operated by the US Defense Department, is increasingly used by surveyors. Even ordinary hikers, sailors and explorers can tap into it for data telling them where they are. Simplified civilian versions of the receivers are available for a few hundred dollars and they are also the heart of electronic map displays available in some cars. Cartography is pressing on to cosmic frontiers, but its objective is, and always has been, to communicate a sense of ‘here’ in relation to ‘there’, however far away ‘there’ may be.
Questions 1 – 5
Choose the correct answer, A, B, C or D.
1. According to the first paragraph, mapmakers in the 21st century
A. combine techniques to chart unknown territory.
B. still rely on being able to see what they map.
C. are now able to visit the darkest jungle.
D. need input from experts in other fields.
2. The Library of Congress offers an opportunity to
A. borrow from their collection of Dutch maps.
B. learn how to restore ancient and fragile maps.
C. enjoy the atmosphere of the reading room.
D. create individual computer maps to order.
3. Ptolemy alerted his contemporaries to the importance of
A. measuring the circumference of the world.
B. organising maps to reflect accurate ratios of distance.
C. working out the distance between parallels of latitude.
D. accuracy and precision in mapping.
4. The invention of the printing press
A. revitalized interest in scientific knowledge.
B. enabled maps to be produced more cheaply.
C. changed the approach to mapmaking.
D. ensured that the work of Ptolemy was continued.
5. writer concludes by stating that
A. mapmaking has become too specialized.
B. cartographers work in very harsh conditions.
C. the fundamental aims of mapmaking remain unchanged.
D. the possibilities of satellite mapping are infinite.
Choose the correct mapmaker corresponding to the achievement in question 6 – 8
6. came very close to accurately measuring the distance round the Earth.
A. Mercator
B. Ptolemy
C. Cassini family
D. Eratosthenes
7. produced maps showing man-made landmarks.
A. Mercator
B. Ptolemy
C. Cassini family
D. Eratosthenes
8. laid the foundation for our modern time zones.
A. Mercator
B. Ptolemy
C. Cassini family
D. Eratosthenes
Questions 9 – 13
Complete the summary below and choose answers in options below
Ancient maps allow us to see how we have come to make sense of the world. They also reflect the attitudes and knowledge of the day. The first great step in mapmaking took place in 9 ……………………. A. France B. Egypt C. USA D. South Africa in the 3rd century BC. Work continued in this tradition until the 2nd century AD but was then abandoned for over a thousand years, during which time maps were the responsibility of 10 ………… A. Sailors B. Monks C. Cartographers D. Mapmakers rather than scientists. Fortunately, however, the writings of 11 ……………………. A. Eratosthenes B . Ptolemy C. Cassini Family D. Mercator had been kept, and interest in scientific mapmaking was revived as scholars sought to produce maps, inspired by the accounts of travelers. These days, 12 ………………………. A. Scientific Knowledge B. Navigational Satellites C. Surveyors D. Mapmakers are vital to the creation of maps and radar has allowed cartographers to map areas beyond our immediate world. In addition, this high-tech equipment is not only used to map faraway places, but cheaper versions have also been developed for use in 13………………………………… A. Aircraft B. Some Cars C. Ship D. Vehicles
Choose your answers in the options below
9 ………….
A. France
B. Egypt
C. USA
D. South Africa
10 ………………
A. Sailors
B. Monks
C. Cartographers
D. Mapmakers
11 ……………..
A. Eratosthenes
B . Ptolemy
C. Cassini Family
D. Mercator
12 …………
A. Scientific Knowledge
B. Navigational Satellites
C. Surveyors
D. Mapmakers
13 …………….
A. Aircraft
B. Some Cars
C. Ship
D. Vehicles
Verbal Aptitude – Use the following Information to answer Questions 14 – 15
3 Years ago, Ade was 5 and his mother was 5 times his age.
14. How old will his mother be in 4 years time?
A. 30
B. 42
C. 36
D. 32
15. How old will Ade be in 4 years time?
A. 12
B. 10
C. 15
D. 13
Use the information below to answer questions 16 – 20
Tolu and Goke together had 18 sweets. Goke and Yinka together had 22 sweets. Together the three of them had 30 sweets.
16. Tolu had ——– Sweets.
A. 9
B. 10
C. 8
D. 12
17. Goke had ——– sweets.
A. 9
B. 10
C. 8
D. 12
18. Yinka had ——– sweets
A.12
B. 10
C. 9
D. 15
19. How many sweets must Yinka give Tolu for all to have the same number?
A. 1
B. 4
C. 2
D.6
20. If Tolu gave four sweets to Yinka, how many times more sweets would Yinka have than Tolu?
A. 3
B. 4
C. 2
D. 0
Quantitative Aptitude
21. How many types of fractions do we have?
A.1
B.2
C.3
D.4
22. ¾ is an example of
A. equivalent fraction
B. Mixed fraction
C. improper Fraction
D. Proper Fraction
23. 6 is a factor of which of the following numbers?
A. 10
B. 26
C. 18
D. 19
24. How many distinct prime factors does the number 36 have?
A. 2
B. 3
C. 4
D. 5
25. The percentage decrease of 8 to 6 is equal to the percentage decrease from 40 to what number?
A. 3
B. 10
C. 25
D. 30
Miscellaneous Questions
26. The Eagle in the Nigerian Coat of Arms represents
A. Dignity
B. Loyalty
C. Strength
D. Wealth
27. Who is the first Nigerian to win an Olympic Gold Medal?
A. Mary Onyali
B. Sunday Bada
C. Chioma Ajunwa
D. Falilat Ogunkoya
28. The place where two rivers meet and flow together is called
A. Boundary
B. Junction
C. Confluence
D. Meeting point
29. Who is the Pro Chancellor of FUTES?
A. Binta Garba
B. Opeyemi Bamidele
C. Dayo Adeyeye
D. Biodun Olujinmi
30. Which Greenwich Meridian Time (GMT) is applicable to Nigeria?
A. GMT +2
B. GMT+1
C. GMT- 2
D.GMT -3
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