network Editorial O n 15 March, the IMA and LMS jointly presented the 2017 David Crighton Medal to former IMA President Professor David Abrahams at the Royal Society. This medal is awarded ev- ery two years to an eminent mathematician for services both to mathematics and to the mathematical community. As Director of the Isaac Newton Institute for Mathe- matical Sciences in Cambridge and former Beyer Professor of Applied Mathematics at the University of Manchester, David is a worthy recipient. He followed this award with a fascinating lecture on Mathematics, Metamaterials and Meteorites. Two other notable one-day meetings are worth mentioning here. Firstly, the 12th annual conference IMA Mathemat- ics 2018 was held in London and com- prised several talks by prominent speak- ers including David, current President Maria Gaetana Agnesi (1718–1799) enables access to both the Italian origi- nal and an English translation by the Rev- erend John Colson in 1801. He was the Lucasian Professor of Mathematics at Cambridge University and also translated De Methodis Serierum et Fluxionum by Sir Isaac Newton from Latin to English in 1736. The tale concerning Maria’s profes- sorial appointment is remarkable. Pope Benedict XIV was knowledgeable in math- ematics and was highly impressed with this published work [1], to the extent that he personally appointed her as an hon- orary reader at the University of Bologna. The Pope and the university’s president subsequently invited her to accept the chair of mathematics in 1750, though it is likely that she never actively engaged in this position as she became director of the Hospice Trivulzio of the Blue Nuns in Professor Alistair Fitt and former Council Member Rear Ad- miral Nigel Guild. As in previous years, this was a popular and enjoyable occasion that offered welcome opportunities to mingle with other delegates. Secondly, the IMA Early Career Mathematicians’ Spring Conference was postponed due to ad- verse weather conditions, and will now be held on 21 April at Durham University. The current ECM chair is Dr Chris Baker who, after short spells in academia and industry, se- cured a Mathematics Teacher Training Scholarship and now teaches mathematics and computer science to secondary and A-level students. I was delighted to hear that the judging panel decided to award the 2017 Catherine Richards Prize to Professor Alan Champneys for his article Boardmasters, which appeared in last August’s is- sue. He has published several excellent features as part of the popular Westward Ho! series that began a year ago and this arti- cle was particularly impressive. As always, I am grateful to the volunteer judges for their efforts. Next month, we celebrate the 300th anniversary of the birth of Italian mathematician Maria Gaetana Agnesi. A remarkable person, she was born in Milan on 16 May 1718, was incredibly talented, had a distinguished career and lived to 80 years of age. She was the first woman appointed as a mathematics professor, indeed at the prestigious University of Bologna. She was also a philosopher, theologian and humanitarian, while one of her many siblings, Maria Teresa Agnesi Pinottini (1720–1795), was a fa- mous composer and musician. Maria was the first woman to write a mathematics handbook, Instituzioni Analitiche ad Uso della Gioventù Italiana (Analyt- ical Institutions for the Use of Italian Youth), in 1748. She in- tended this to provide a systematic illustration of the different re- sults and theorems of calculus, by combining algebra with anal- ysis. This was the first book that discussed both differential and integral calculus, and appeared in two hefty volumes on finite quantities and infinitesimals. According to [1], the Académie des Sciences in Paris regarded Maria’s handbook as, ‘the most com- plete and best made treatise’. The website books.google.co.uk Milan and remained there until her death on 9 January 1799. She was the second woman ever to be granted a university chair, the first being Italian physicist Laura Bassi (1711–1778). Although Maria’s writings were expository in nature rather than original theoretical developments, she tackled many chal- lenging problems. Among those, she analysed a cubic curve that had been studied by Pierre de Fermat in 1630 and Guido Grandi in 1703. Grandi subsequently introduced the expression la versiera to describe this curve, based on a Latin word for rope, and Maria adopted this term. Colson seemingly translated this as the witch, based on the Italian noun l’avversiera. Consequently, this mathe- matical curve is now generally referred to as the witch of Agnesi. It can be defined as the hyperbolism [2] of a circle relative to one of its points and the tangent that is diametrically opposite to this point, as illustrated in Figure 1. Figure 1: Construction method for the witch of Agnesi The Cartesian equation for this curve is y = 1 x 2 +1 © Sheila Terry | Science Photo Library Mathematics TODAY APRIL 2018 42
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networkEditorialEditorial
O n 15 March, the IMA and LMSjointly presented the 2017 DavidCrighton Medal to former IMA
President Professor David Abrahams at theRoyal Society. This medal is awarded ev-ery two years to an eminent mathematicianfor services both to mathematics and tothe mathematical community. As Directorof the Isaac Newton Institute for Mathe-matical Sciences in Cambridge and formerBeyer Professor of Applied Mathematicsat the University of Manchester, David is aworthy recipient. He followed this awardwith a fascinating lecture on Mathematics,Metamaterials and Meteorites.
Two other notable one-day meetingsare worth mentioning here. Firstly, the12th annual conference IMA Mathemat-ics 2018 was held in London and com-prised several talks by prominent speak-ers including David, current President Maria Gaetana Agnesi (1718–1799)
enables access to both the Italian origi-nal and an English translation by the Rev-erend John Colson in 1801. He wasthe Lucasian Professor of Mathematics atCambridge University and also translatedDe Methodis Serierum et Fluxionum bySir Isaac Newton from Latin to Englishin 1736.
The tale concerning Maria’s profes-sorial appointment is remarkable. PopeBenedict XIV was knowledgeable in math-ematics and was highly impressed withthis published work [1], to the extent thathe personally appointed her as an hon-orary reader at the University of Bologna.The Pope and the university’s presidentsubsequently invited her to accept thechair of mathematics in 1750, though itis likely that she never actively engagedin this position as she became director ofthe Hospice Trivulzio of the Blue Nuns in
Professor Alistair Fitt and former Council Member Rear Ad-miral Nigel Guild. As in previous years, this was a popularand enjoyable occasion that offered welcome opportunities tomingle with other delegates. Secondly, the IMA Early CareerMathematicians’ Spring Conference was postponed due to ad-verse weather conditions, and will now be held on 21 Aprilat Durham University. The current ECM chair is Dr ChrisBaker who, after short spells in academia and industry, se-cured a Mathematics Teacher Training Scholarship and nowteaches mathematics and computer science to secondary andA-level students.
I was delighted to hear that the judging panel decided to awardthe 2017 Catherine Richards Prize to Professor Alan Champneysfor his article Boardmasters, which appeared in last August’s is-sue. He has published several excellent features as part of thepopular Westward Ho! series that began a year ago and this arti-cle was particularly impressive. As always, I am grateful to thevolunteer judges for their efforts.
Next month, we celebrate the 300th anniversary of the birthof Italian mathematician Maria Gaetana Agnesi. A remarkableperson, she was born in Milan on 16 May 1718, was incrediblytalented, had a distinguished career and lived to 80 years of age.She was the first woman appointed as a mathematics professor,indeed at the prestigious University of Bologna. She was also aphilosopher, theologian and humanitarian, while one of her manysiblings, Maria Teresa Agnesi Pinottini (1720–1795), was a fa-mous composer and musician.
Maria was the first woman to write a mathematics handbook,Instituzioni Analitiche ad Uso della Gioventù Italiana (Analyt-ical Institutions for the Use of Italian Youth), in 1748. She in-tended this to provide a systematic illustration of the different re-sults and theorems of calculus, by combining algebra with anal-ysis. This was the first book that discussed both differential andintegral calculus, and appeared in two hefty volumes on finitequantities and infinitesimals. According to [1], the Académie desSciences in Paris regarded Maria’s handbook as, ‘the most com-plete and best made treatise’. The website books.google.co.uk
Milan and remained there until her death on 9 January 1799. Shewas the second woman ever to be granted a university chair, thefirst being Italian physicist Laura Bassi (1711–1778).
Although Maria’s writings were expository in nature ratherthan original theoretical developments, she tackled many chal-lenging problems. Among those, she analysed a cubic curve thathad been studied by Pierre de Fermat in 1630 and Guido Grandi in1703. Grandi subsequently introduced the expression la versierato describe this curve, based on a Latin word for rope, and Mariaadopted this term. Colson seemingly translated this as the witch,based on the Italian noun l’avversiera. Consequently, this mathe-matical curve is now generally referred to as the witch of Agnesi.It can be defined as the hyperbolism [2] of a circle relative to oneof its points and the tangent that is diametrically opposite to thispoint, as illustrated in Figure 1.
Figure 1: Construction method for the witch of Agnesi
The Cartesian equation for this curve is
y =1
x2 + 1
© S
heila
Ter
ry |
Sci
ence
Pho
to L
ibra
ry
Mathematics TODAY APRIL 2018 42
David F. Percy CMath CSci FIMAUniversity of Salford
RefeRences
1 O’Connor, J.J. and Robertson, E.F. (1999) Maria Gaëtana Ag-nesi, MacTutor History of Mathematics, University of St Andrews, www-history.mcs.st-andrews.ac.uk/Biographies/Agnesi.html (accessed 28 February 2018).
2 Ferréol, R. (2017) Hyperbolism and antihyperbolism of a curve: Newton transformation, Mathcurve, www.mathcurve.com/courbes2d.gb/hyperbolisme/hyperbolisme.shtml (accessed 28 February 2018).
3 Shmueli, G., Minka, T.P., Kadane, J.B., et al. (2005) A useful dis-tribution for fitting discrete data: revival of the Conway–Maxwell–Poisson distribution, J. R. Stat. Soc. Ser. C, vol. 54, pp. 127–142.
and it has some intriguing properties. In particular, it isthe derivative of the arctangent function and approximates thespectral energy distribution of X-ray lines, the surface shape ofa single water wave and the cross-sectional profile of a smoothhill. It also defines the probability density function (PDF) of thestandard Cauchy distribution
f(x) =1
π(x2 + 1), x ∈ R,
which is equivalent to Student’s t(ν) distribution with ν = 1. ItsPDF is displayed in Figure 2 with those of the t(3) and standardnormal distributions for comparison: the last of these is equiva-lent to t(∞). The median and mode of the t(ν) distribution areboth zero for ν > 0. Although the mean is also zero for ν > 1,amazingly it is undefined for ν ≤ 1 (including the Cauchy distri-bution) despite the PDF’s obvious symmetry and unimodality.
86420-2-4-6-8
0.4
0.3
0.2
0.1
0.0
Figure 2: Cauchy, t and normal PDFs
I encountered another interesting probability distribution lastNovember at a conference in the beautiful city of Samsun on theBlack Sea coast of Turkey. This event was organised by my firstPhD student, Mehmet Ali Cengiz, who is now a professor andvice rector at Ondokuz Mayıs University. One of the keynotespeakers was Professor Narayanaswamy Balakrishnan of Mc-Master University (Canada), who presented a lecture on flexiblecure models for medical research. What particularly caught myattention was his application of the surprisingly underused COM-Poisson distribution [3] with probability mass function (PMF):
p(x) =1
Z(λ, ν)
λx
(x!)ν, x ∈ {0, 1, . . .},
where Z(λ, ν) is a normalising constant, an intractable functionof parameters λ > 0 and ν ≥ 0 subject to λ < 1 if ν = 0.
This generalises the Poisson distribution, which correspondsto the special case with ν = 1 but is often too restrictive as itsmean and variance are equal. Although the negative binomial dis-tribution resolves problems of over-dispersion, the COM-Poissondistribution can also model under-dispersion. Moreover, it re-duces to the Bernoulli distribution in the limit as ν → ∞ andthe geometric distribution on setting ν = 0. These convolve tobinomial and negative binomial distributions respectively, so thismodel offers a flexible alternative for analysing count data. Fig-ure 3 displays illustrative PMFs for these special cases.
876543210
0.5
0.4
0.3
0.2
0.1
0.0
…
Figure 3: Bernoulli, geometric and Poisson PMFs
Finally, I cannot resist mentioning our adorable new puppy,Monty. He chews pretty much anything and can undo shoelacebows and the zip on his soft kennel, though at least he respondswell to recall and fetch commands. My mother already spoils himwith titbits when we visit.
Anyway, I shall try to read April’s issue of Mathematics To-day before he gets his gnashers on it and I hope that you too enjoyreading the various notices, reviews, features and puzzles on of-fer. I leave you with a simple limerick over which to mull:
My name is Maria Agnesi,And some folks are driving me crazy.They call me a witch;It’s a bit of a hitch;I’m really a saint Milanese.
David F. Percy CMath CSci FIMAUniversity of Salford
References1 O’Connor, J.J. and Robertson, E.F. (1999) Maria Gaëtana Agnesi,
MacTutor History of Mathematics, University of St Andrews,www-history.mcs.st-andrews.ac.uk/Biographies/Agnesi.html (accessed 28 February 2018).
2 Ferréol, R. (2017) Hyperbolism and antihyperbolism of a curve: New-ton transformation, Mathcurve, www.mathcurve.com/courbes2d.gb/hyperbolisme/hyperbolisme.shtml (accessed 28 February2018).
3 Shmueli, G., Minka, T.P., Kadane, J.B., et al. (2005) A useful distribu-tion for fitting discrete data: revival of the Conway–Maxwell–Poissondistribution, J. R. Stat. Soc. Ser. C, vol. 54, pp. 127–142.
and it has some intriguing properties. In particular, it isthe derivative of the arctangent function and approximates thespectral energy distribution of X-ray lines, the surface shape ofa single water wave and the cross-sectional profile of a smoothhill. It also defines the probability density function (PDF) of thestandard Cauchy distribution
f(x) =1
π(x2 + 1), x ∈ R,
which is equivalent to Student’s t(ν) distribution with ν = 1. ItsPDF is displayed in Figure 2 with those of the t(3) and standardnormal distributions for comparison: the last of these is equiva-lent to t(∞). The median and mode of the t(ν) distribution areboth zero for ν > 0. Although the mean is also zero for ν > 1,amazingly it is undefined for ν ≤ 1 (including the Cauchy distri-bution) despite the PDF’s obvious symmetry and unimodality.
86420-2-4-6-8
0.4
0.3
0.2
0.1
0.0
Figure 2: Cauchy, t and normal PDFs
I encountered another interesting probability distribution lastNovember at a conference in the beautiful city of Samsun on theBlack Sea coast of Turkey. This event was organised by my firstPhD student, Mehmet Ali Cengiz, who is now a professor andvice rector at Ondokuz Mayıs University. One of the keynotespeakers was Professor Narayanaswamy Balakrishnan of Mc-Master University (Canada), who presented a lecture on flexiblecure models for medical research. What particularly caught myattention was his application of the surprisingly underused COM-Poisson distribution [3] with probability mass function (PMF):
p(x) =1
Z(λ, ν)
λx
(x!)ν, x ∈ {0, 1, . . .},
where Z(λ, ν) is a normalising constant, an intractable functionof parameters λ > 0 and ν ≥ 0 subject to λ < 1 if ν = 0.
This generalises the Poisson distribution, which correspondsto the special case with ν = 1 but is often too restrictive as itsmean and variance are equal. Although the negative binomial dis-tribution resolves problems of over-dispersion, the COM-Poissondistribution can also model under-dispersion. Moreover, it re-duces to the Bernoulli distribution in the limit as ν → ∞ andthe geometric distribution on setting ν = 0. These convolve tobinomial and negative binomial distributions respectively, so thismodel offers a flexible alternative for analysing count data. Fig-ure 3 displays illustrative PMFs for these special cases.
876543210
0.5
0.4
0.3
0.2
0.1
0.0
…
Figure 3: Bernoulli, geometric and Poisson PMFs
Finally, I cannot resist mentioning our adorable new puppy,Monty. He chews pretty much anything and can undo shoelacebows and the zip on his soft kennel, though at least he respondswell to recall and fetch commands. My mother already spoils himwith titbits when we visit.
Anyway, I shall try to read April’s issue of Mathematics To-day before he gets his gnashers on it and I hope that you too enjoyreading the various notices, reviews, features and puzzles on of-fer. I leave you with a simple limerick over which to mull:
My name is Maria Agnesi,And some folks are driving me crazy.They call me a witch;It’s a bit of a hitch;I’m really a saint Milanese.
David F. Percy CMath CSci FIMAUniversity of Salford
References1 O’Connor, J.J. and Robertson, E.F. (1999) Maria Gaëtana Agnesi,
MacTutor History of Mathematics, University of St Andrews,www-history.mcs.st-andrews.ac.uk/Biographies/Agnesi.html (accessed 28 February 2018).
2 Ferréol, R. (2017) Hyperbolism and antihyperbolism of a curve: New-ton transformation, Mathcurve, www.mathcurve.com/courbes2d.gb/hyperbolisme/hyperbolisme.shtml (accessed 28 February2018).
3 Shmueli, G., Minka, T.P., Kadane, J.B., et al. (2005) A useful distribu-tion for fitting discrete data: revival of the Conway–Maxwell–Poissondistribution, J. R. Stat. Soc. Ser. C, vol. 54, pp. 127–142.
N (0,1)
t (3)
C (0,1)
B (0.5)
G (0.3)
P (3)
x
x
f(x)
p(x)
Mathematics TODAY APRIL 2018 43
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