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July 5, 2023

Estimating the distance and speed of a receding vehicle

Filed under: mathematics — ckrao @ 6:24 am

Imagine a car or truck speeding away in front of you on the road. Here is a rough method to estimate its distance and speed using your outstretched hand (try this as a passenger, not a driver!).

At any given time its distance away is approximately

$\displaystyle \frac{57\times \text{width of vehicle}}{\text{angle in degrees}}.\quad\quad(1)$

We use the figure below to estimate angles based on our outstretched hand at arm’s length:

Hence a vehicle that is 2m wide subtending an angle of 5 degrees (3 fingers at arm’s length) is about 23m away. At 1 degree (1 little finger at arm’s length) it is about 115m away.

Then measure the time T (in seconds) it takes to go from 3 fingers width (5 degrees) to 1 little finger width (1 degree) at arm’s length. Its relative speed in km/h is approximately given by

$\displaystyle \frac{165\times \text{width of vehicle in metres}}{\text{T}}.\quad\quad(2)$

For example, if a 2m-wide car takes 33 seconds to go from 3 fingers to 1 little finger width at arm’s length (115-23=92 m in distance), it is going 10km/h faster than I am.

To justify these formulas, the figure below shows segment BC of width w at distance d from A, subtending an angle of $\theta$ . Using trigonometry we find $d = (w/2)\cot (\theta/2)$ . For small angles, $\cot (\theta/2) \approx 2/\theta_r$ where $\theta_r$ is measured in radians, an approximation that is only around 1% inaccurate even when $\theta$ is as large as 20 degrees.

Formula (1) then follows from $d = (w/2) \cot (\theta/2) \approx (w/2)\times (2/\theta_r) = w/\theta_r$ and the fact that angles $\theta_r$ in radians are $\pi/180 \approx 1/57$ times angles $\theta_d$ in degrees.

Formula (2) is true since we are covering a distance $(w/2) \left( \cot \frac{1}{2}^{\circ} - \cot \frac{5}{2}^{\circ} \right) \approx (w/2)\frac{180}{\pi} \left( \frac{2}{1} - \frac{2}{5}\right)$ in time T. Multiplying this by 3.6 to convert from m/s to km/h gives us the approximate scale factor of 165.

The table below shows some sample values for a car with width 2m and truck with width 3m.

Angle subtended by object (degrees)	Width of vehicle (m)	Distance of object (m)	Approximate distance using (1)
20	2	5.7	5.7
10	2	11	11
5	2	23	23
1	2	115	114
0.02	2	5730	5700
20	3	8.5	8.6
10	3	17	17
5	3	34	34
1	3	172	171
0.02	3	8600	8550

Distance estimates based on the angle and width of an object.

The smallest angle of 0.02° (~1 minute) approximately corresponds to the smallest object we can resolve with the naked eye.

The next table shows estimates of receding speeds based on going from 5° to 1° of angular diameter.

Width of vehicle (m)	Time (s) to go from 5° to 1°	Estimated speed (km/h)
2	3	110
2	5	66
2	10	33
2	33	10
3	5	99
3	10	50
3	33	15

Speed estimates based on the width and time taken to go from 5° down to 1°.

Reference:

https://en.wikipedia.org/wiki/Angular_diameter

Comments (1)

February 15, 2022

Some cricket stats by test series

Filed under: cricket,sport — ckrao @ 10:31 am

Below is a list of some statistics related to performances across test series. They are current up to 15 February 2022. Data is from ESPNcricinfo.

Most series playing 5 or more tests:

AR Border (AUS)	15
RB Kanhai (WI)	14
IVA Richards (WI)	14
AJ Stewart (ENG)	13
GS Sobers (WI)	13
MA Atherton (ENG)	13
CA Walsh (WI)	13
DI Gower (ENG)	12
RN Harvey (AUS)	12
CG Greenidge (WI)	12
GA Gooch (ENG)	12

Most series playing 3 or more tests:

SR Tendulkar (INDIA)	44
RT Ponting (AUS)	39
SR Waugh (AUS)	39
SK Warne (AUS)	38
AR Border (AUS)	37
R Dravid (INDIA)	36
AN Cook (ENG)	35
JM Anderson (ENG)	35
Javed Miandad (PAK)	33
ME Waugh (AUS)	33
JH Kallis (SA)	32
N Kapil Dev (INDIA)	31
DPMD Jayawardene (SL)	31

Most series played:

SR Tendulkar (INDIA)	74
S Chanderpaul (WI)	60
DPMD Jayawardene (SL)	60
M Muralitharan (SL)	60
JH Kallis (SA)	60
RT Ponting (AUS)	59
R Dravid (INDIA)	59
JM Anderson (ENG)	58
KC Sangakkara (SL)	56
SR Waugh (AUS)	54
SCJ Broad (ENG)	53
ST Jayasuriya (SL)	53
MV Boucher (SA)	52
LRPL Taylor (NZ)	52
A Kumble (INDIA)	51
Inzamam-ul-Haq (PAK)	51
DL Vettori (NZ)	51

Most series scoring at least r runs:

(Click on the image to change r in Tableau.)

Most series taking at least w wickets:

(Click on the image to change w in Tableau.)

Most series scoring at least r runs and taking at least w wickets:

(Click on the image to change r and w in Tableau.)

Never batting having played in 3+ tests in a series:

CF Root (ENG)	The Ashes (Australia in England), 1926
GD McGrath (AUS)	Sri Lanka in Australia Test Series, 1995/96
PR Adams (SA)	South Africa in New Zealand Test Series, 1998/99
SL Malinga (SL)	Bangladesh in Sri Lanka Test Series, 2007
M Muralitharan (SL)	Bangladesh in Sri Lanka Test Series, 2007
JR Hazlewood (AUS)	The Frank Worrell Trophy (West Indies in Australia), 2015/16
NM Lyon (AUS)	The Frank Worrell Trophy (West Indies in Australia), 2015/16
JL Pattinson (AUS)	The Frank Worrell Trophy (West Indies in Australia), 2015/16

All the above played 3 tests in the series – note that 3 players did not bat in the 2015/16 series.

Most consecutive series scoring at least 400 runs:

DG Bradman (AUS)	6
SM Gavaskar (INDIA)	6
AD Nourse (SA)	5
ED Weekes (WI)	4
RB Kanhai (WI)	4
CL Walcott (WI)	3
ED Weekes (WI)	3
GA Gooch (ENG)	3
GS Sobers (WI)	3
H Sutcliffe (ENG)	3
DCS Compton (ENG)	3
ER Dexter (ENG)	3
SJ McCabe (AUS)	3
B Mitchell (SA)	3
IR Redpath (AUS)	3
IVA Richards (WI)	3

Most consecutive series taking at least 20 wickets:

MD Marshall (WI)	7
FS Trueman (ENG)	6
WJ O’Reilly (AUS)	5
WA Johnston (AUS)	5
EAS Prasanna (INDIA)	4
CV Grimmett (AUS)	4
FS Trueman (ENG)	4
AK Davidson (AUS)	4
DK Lillee (AUS)	4

Most 50+ scores in a test series:

Player	50+	Series	Matches	Inns	NO	Runs	HS	100
G Boycott (ENG)	7	The Ashes (England in Australia), 1970/71	5	10	3	657	142*	2
RN Harvey (AUS)	7	South Africa in Australia Test Series, 1952/53	5	9	0	834	205	4
AD Nourse (SA)	7	South Africa in England Test Series, 1947	5	9	0	621	149	2
SM Gavaskar (INDIA)	7	India in West Indies Test Series, 1970/71	4	8	3	774	220	4
GS Chappell (AUS)	7	The Ashes (England in Australia), 1974/75	6	11	0	608	144	2
EH Hendren (ENG)	7	England in West Indies Test Series, 1929/30	4	8	2	693	205*	2
CL Walcott (WI)	7	Australia in West Indies Test Series, 1955	5	10	0	827	155	5
GA Faulkner (SA)	7	South Africa in Australia Test Series, 1910/11	5	10	0	732	204	2
MA Taylor (AUS)	7	The Ashes (Australia in England), 1989	6	11	1	839	219	2

Most 5-wicket hauls in a series:

Player	5+	Series	Matches	Inns	Wkts	BBI	BBM	Ave	Econ	SR	10
SF Barnes (ENG)	7	England in South Africa Test Series, 1913/14	4	8	49	9/103	17/159	10.93	2.37	27.6	3
TM Alderman (AUS)	6	The Ashes (Australia in England), 1989	6	11	41	6/128	10/151	17.36	2.64	39.4	1
CV Grimmett (AUS)	5	Australia in South Africa Test Series, 1935/36	5	10	44	7/40	13/173	14.59	1.85	47.2	3
Sir RJ Hadlee (NZ)	5	Trans-Tasman Trophy (New Zealand in Australia), 1985/86	3	6	33	9/52	15/123	12.15	2.36	30.8	2
SF Barnes (ENG)	5	South Africa in England Test Series, 1912	3	6	34	8/29	13/57	8.29	2.20	22.5	3
AV Bedser (ENG)	5	The Ashes (Australia in England), 1953	5	10	39	7/44	14/99	17.48	2.57	40.7	1
RM Hogg (AUS)	5	The Ashes (England in Australia), 1978/79	6	11	41	6/74	10/66	12.85	1.81	42.4	2
MW Tate (ENG)	5	The Ashes (England in Australia), 1924/25	5	10	38	6/99	11/228	23.18	2.09	66.5	1
AK Davidson (AUS)	5	The Frank Worrell Trophy (West Indies in Australia), 1960/61	4	8	33	6/53	11/222	18.54	2.63	42.1	1

Most runs in a series without scoring 50:


Player	Runs	Series	Matches	Inns	NO	HS
VS Ransford (AUS)	252	The Ashes (England in Australia), 1911/12	5	10	2	43
GM Ritchie (AUS)	244	The Ashes (England in Australia), 1986/87	4	8	2	46*
LC Braund (ENG)	233	The Ashes (England in Australia), 1907/08	5	10	1	49
AE Relf (ENG)	229	England in South Africa Test Series, 1905/06	5	10	0	37
JM Gregory (AUS)	224	The Ashes (England in Australia), 1924/25	5	10	1	45
HA Gomes (WI)	223	West Indies in India Test Series, 1983/84	6	10	3	38
Majid Khan (PAK)	222	India in Pakistan Test Series, 1978/79	3	6	0	47
MHN Walker (AUS)	221	The Ashes (England in Australia), 1974/75	6	8	3	41*
JH Edrich (ENG)	218	The Ashes (Australia in England), 1972	5	10	0	49

Most runs in a series without scoring a century:

Player	Runs	Series	Matches	Inns	NO	HS	Ave	50	0
MA Atherton (ENG)	553	The Ashes (Australia in England), 1993	6	12	0	99	46.08	6	0
CC Hunte (WI)	550	The Frank Worrell Trophy (Australia in West Indies), 1964/65	5	10	1	89	61.11	6	0
C Hill (AUS)	521	The Ashes (England in Australia), 1901/02	5	10	0	99	52.10	4	1
GP Thorpe (ENG)	506	The Wisden Trophy (West Indies in England), 1995	6	12	0	94	42.16	5	2
RB Kanhai (WI)	497	The Wisden Trophy (West Indies in England), 1963	5	9	0	92	55.22	4	0
ER Dexter (ENG)	481	The Ashes (England in Australia), 1962/63	5	10	0	99	48.10	5	0
GR Viswanath (INDIA)	473	India in Australia Test Series, 1977/78	5	9	0	89	52.55	5	0
HH Gibbs (SA)	464	Sir Vivian Richards Trophy (South Africa in West Indies), 2000/01	5	10	1	87	51.55	4	0
TL Goddard (SA)	454	South Africa in Australia Test Series, 1963/64	5	10	3	93	64.85	4	0
SL Campbell (WI)	454	The Wisden Trophy (West Indies in England), 1995	6	10	0	93	45.40	4	0

Most wickets in a series without 5 in an innings:

Player	Wkts	Series	Matches	Inns	BBI	BBM	Ave	Econ	SR
PJ Cummins (AUS)	29	The Ashes (Australia in England), 2019	5	10	4/32	7/103	19.62	2.69	43.6
WM Clark (AUS)	28	India in Australia Test Series, 1977/78	5	9	4/46	8/147	25.03	2.65	56.6
J Garner (WI)	27	The Wisden Trophy (England in West Indies), 1985/86	5	10	4/43	7/58	16.14	2.79	34.7
MD Marshall (WI)	27	The Wisden Trophy (England in West Indies), 1985/86	5	10	4/38	8/132	17.85	2.84	37.6
SR Clark (AUS)	26	The Ashes (England in Australia), 2006/07	5	10	4/72	7/93	17.03	2.27	44.8
J Garner (WI)	26	The Wisden Trophy (West Indies in England), 1980	5	10	4/30	7/74	14.26	1.74	49.0
DK Lillee (AUS)	25	The Ashes (England in Australia), 1974/75	6	11	4/49	8/118	23.84	2.44	58.4
J Garner (WI)	25	Pakistan in West Indies Test Series, 1976/77	5	10	4/48	8/148	27.52	3.13	52.6
M Ntini (SA)	25	Basil D’Oliveira Trophy (England in South Africa), 2004/05	5	10	4/50	7/173	25.08	2.83	53.1

Most wickets in a series without 10 in a match:

Player	Wkts	Series	Matches	Inns	BBI	BBM	5-fer	Ave	Econ	SR
TM Alderman (AUS)	42	The Ashes (Australia in England), 1981	6	12	6/135	9/130	4	21.26	2.74	46.4
MG Johnson (AUS)	37	The Ashes (England in Australia), 2013/14	5	10	7/40	9/103	3	13.97	2.74	30.5
WJ Whitty (AUS)	37	South Africa in Australia Test Series, 1910/11	5	10	6/17	9/98	2	17.08	2.71	37.7
GD McGrath (AUS)	36	The Ashes (Australia in England), 1997	6	12	8/38	9/103	2	19.47	2.80	41.6
BS Chandrasekhar (INDIA)	35	England in India Test Series, 1972/73	5	9	8/79	9/107	4	18.91	2.27	49.9
SF Barnes (ENG)	34	The Ashes (England in Australia), 1911/12	5	10	5/44	8/140	3	22.88	2.61	52.4
SK Warne (AUS)	34	The Ashes (Australia in England), 1993	6	12	5/82	8/137	1	25.79	1.99	77.6
SP Gupte (INDIA)	34	New Zealand in India Test Series, 1955/56	5	10	7/128	9/145	4	19.67	1.87	62.9
G Giffen (AUS)	34	The Ashes (England in Australia), 1894/95	5	9	6/155	8/40	3	24.11	2.31	62.5

Most runs scored in a player’s lowest-scoring series:

Player	Runs	#Series
BA Richards (SA)	508	1
PGV van der Bijl (SA)	460	1
DG Bradman (AUS)	396	11
BL Irvine (SA)	353	1
J Hardstaff snr (ENG)	311	1
DS Steele (ENG)	308	2

Most wickets in lowest wicket-taking series:

Player	Wkts	#Series
AS Kennedy (ENG)	31	1
GB Lawrence (SA)	28	1
WS Lees (ENG)	26	1
GF Bissett (SA)	25	1
GHT Simpson-Hayward (ENG)	23	1

Most balls bowled in a series without taking a wicket:

Player	Balls	Series	Matches	Runs	Econ
JE Emburey (ENG)	642	Pakistan in England Test Series, 1987	4	222	2.07
RDB Croft (ENG)	522	South Africa in England Test Series, 1998	3	211	2.42
Arshad Ayub (INDIA)	516	India in Pakistan Test Series, 1989/90	2	300	3.48
Harbhajan Singh (INDIA)	486	India in Pakistan Test Series, 2005/06	2	355	4.38
JL Hopwood (ENG)	462	The Ashes (Australia in England), 1934	2	155	2.01
DB Pithey (SA)	440	South Africa in Australia Test Series, 1963/64	3	239	3.25
WPUJC Vaas (SL)	426	Pakistan in Sri Lanka Test Series, 2000	3	154	2.16
MN Hart (NZ)	426	West Indies in New Zealand Test Series, 1994/95	2	256	3.60
WER Somerville (NZ)	414	New Zealand in India Test Series, 2021/22	2	237	3.43
R Illingworth (ENG)	408	New Zealand in England Test Series, 1973	3	139	2.04

Most times the leading run-scorer in a series (both teams):

KC Sangakkara (SL)	14
SR Tendulkar (INDIA)	11
JH Kallis (SA)	10
BC Lara (WI)	9
RT Ponting (AUS)	9
Javed Miandad (PAK)	8
GC Smith (SA)	8
GA Gooch (ENG)	8
SM Gavaskar (INDIA)	8
JE Root (ENG)	8
FDM Karunaratne (SL)	8
DPMD Jayawardene (SL)	8
KS Williamson (NZ)	8

Most times the leading run-scorer in a series (for their team):

SR Tendulkar (INDIA)	20
KC Sangakkara (SL)	19
BC Lara (WI)	17
R Dravid (INDIA)	16
JH Kallis (SA)	15
LRPL Taylor (NZ)	14
SM Gavaskar (INDIA)	13
JE Root (ENG)	13
Tamim Iqbal (BAN)	12
S Chanderpaul (WI)	12
KS Williamson (NZ)	12
DPMD Jayawardene (SL)	12
SP Fleming (NZ)	12
Javed Miandad (PAK)	12
Younis Khan (PAK)	12

Most times the leading wicket taker in a series (for both teams):

M Muralitharan (SL)	30
A Kumble (INDIA)	23
Sir RJ Hadlee (NZ)	18
DW Steyn (SA)	16
SK Warne (AUS)	16
R Ashwin (INDIA)	15
HMRKB Herath (SL)	13
JM Anderson (ENG)	12
M Ntini (SA)	10
GD McGrath (AUS)	10

Most times the leading runs scorer in a series (for their team):

M Muralitharan (SL)	41
A Kumble (INDIA)	27
Sir RJ Hadlee (NZ)	25
DW Steyn (SA)	21
SK Warne (AUS)	19
HMRKB Herath (SL)	19
R Ashwin (INDIA)	17
JM Anderson (ENG)	17

Most series playing in at least 3 tests and averaging at least 100 with the bat:

RT Ponting (AUS)	6
Javed Miandad (PAK)	5
SPD Smith (AUS)	5
DG Bradman (AUS)	4
SR Waugh (AUS)	4
GS Sobers (WI)	4
SR Tendulkar (INDIA)	4
AB de Villiers (SA)	3
R Dravid (INDIA)	3
V Kohli (INDIA)	3
S Chanderpaul (WI)	3
KC Sangakkara (SL)	3

Most series playing at least 3 tests and averaging at most 20 with the ball (minimum 5 wickets):

GD McGrath (AUS)	12
CEL Ambrose (WI)	9
Imran Khan (PAK)	9
JM Anderson (ENG)	9
Sir RJ Hadlee (NZ)	9
MD Marshall (WI)	8
SK Warne (AUS)	8
M Muralitharan (SL)	8
Wasim Akram (PAK)	7
AA Donald (SA)	7
CA Walsh (WI)	7

Lowest bowling strike rate in a series (minimum 10 wickets):

Player	SR	Series	Matches	Inns	Wkts	Ave	BBI	BBM	5	10
ND Hirwani (INDIA)	12.6	West Indies in India Test Series, 1987/88	1	2	16	8.50	8/61	16/136	2	1
FE Woolley (ENG)	14.0	The Ashes (Australia in England), 1912	3	3	10	5.50	5/20	10/49	2	1
Danish Kaneria (PAK)	14.0	Asian Test Championship (Bangladesh, Pakistan, Sri Lanka in Pakistan/Sri Lanka), 2001/02	1	2	12	7.83	6/42	12/94	2	1
GA Lohmann (ENG)	14.8	England in South Africa Test Series, 1895/96	3	6	35	5.80	9/28	15/45	4	2
MN Samuels (WI)	15.0	Clive Lloyd Trophy (Zimbabwe in West Indies), 2012/13	2	3	10	6.30	4/13	6/50	0	0
JO Holder (WI)	16.0	Bangladesh in West Indies Test Series, 2018	2	4	16	8.93	6/59	11/103	2	1
SR Watson (AUS)	16.2	MCC Spirit of Cricket Test Series (Australia, Pakistan in England), 2010	2	4	11	10.63	6/33	6/51	2	0
DW Steyn (SA)	16.8	New Zealand in South Africa Test Series, 2007/08	2	4	20	9.20	6/49	10/91	3	2
R Peel (ENG)	18.4	The Ashes (Australia in England), 1888	3	6	24	7.54	7/31	11/68	1	1
FR Spofforth (AUS)	18.4	England in Australia Test Match, 1878/79	1	2	13	8.46	7/62	13/110	2	1
FR Spofforth (AUS)	18.5	Australia in England Test Match, 1882	1	2	14	6.42	7/44	14/90	2	1
IK Pathan (INDIA)	18.6	India in Zimbabwe Test Series, 2005	2	4	21	11.28	7/59	12/126	3	1
J Briggs (ENG)	18.6	England in South Africa Test Series, 1888/89	2	4	21	4.80	8/11	15/28	2	1

Lowest bowling average in a series (minimum 10 wickets):

Player	Ave	Series	Matches	Inns	Wkts	SR	BBI	BBM	5	10
J Briggs (ENG)	4.80	England in South Africa Test Series, 1888/89	2	4	21	18.6	8/11	15/28	2	1
FE Woolley (ENG)	5.50	The Ashes (Australia in England), 1912	3	3	10	14.0	5/20	10/49	2	1
WPUJC Vaas (SL)	5.53	West Indies in Sri Lanka Test Series, 2005	2	3	13	22.9	6/22	7/50	1	0
GA Lohmann (ENG)	5.80	England in South Africa Test Series, 1895/96	3	6	35	14.8	9/28	15/45	4	2
MN Samuels (WI)	6.30	Clive Lloyd Trophy (Zimbabwe in West Indies), 2012/13	2	3	10	15.0	4/13	6/50	0	0
FR Spofforth (AUS)	6.42	Australia in England Test Match, 1882	1	2	14	18.5	7/44	14/90	2	1
JJ Ferris (ENG)	7.00	England in South Africa Test Match, 1891/92	1	2	13	20.9	7/37	13/91	2	1
Shoaib Akhtar (PAK)	7.09	Pakistan in New Zealand Test Series, 2003/04	1	2	11	21.0	6/30	11/78	2	1
CTB Turner (AUS)	7.25	The Ashes (England in Australia), 1887/88	1	2	12	29.3	7/43	12/87	2	1
CV Grimmett (AUS)	7.45	The Ashes (England in Australia), 1924/25	1	2	11	22.8	6/37	11/82	2	1
GAR Lock (ENG)	7.47	New Zealand in England Test Series, 1958	5	10	34	31.0	7/35	11/65	3	1
R Peel (ENG)	7.54	The Ashes (Australia in England), 1888	3	6	24	18.4	7/31	11/68	1	1

Most runs without being dismissed:

Player	Runs	Series	Matches	Inns	NO	HS	100	50
JH Kallis (SA)	388	South Africa in Zimbabwe Test Series, 2001/02	2	3	3	189*	2	0
AC Voges (AUS)	375	The Frank Worrell Trophy (West Indies in Australia), 2015/16	3	2	2	269*	2	0
LRPL Taylor (NZ)	364	New Zealand in Zimbabwe Test Series, 2016	2	3	3	173*	2	1
JH Edrich (ENG)	310	New Zealand in England Test Series, 1965	1	1	1	310*	1	0
S Chanderpaul (WI)	270	Bangladesh in West Indies Test Series, 2014	2	3	3	101*	1	2
SR Waugh (AUS)	256	Bangladesh in Australia Test Series, 2003	2	2	2	156*	2	0
IR Bell (ENG)	227	Bangladesh in England Test Series, 2005	2	2	2	162*	1	1
AG Prince (SA)	221	Bangladesh in South Africa Test Series, 2008/09	2	2	2	162*	1	1
JH Kallis (SA)	214	Bangladesh in South Africa Test Series, 2002/03	2	2	2	139*	1	1
Mushfiqur Rahim (BAN)	203	Zimbabwe in Bangladesh Test Match, 2019/20	1	1	1	203*	1	0
DSBP Kuruppu (SL)	201	New Zealand in Sri Lanka Test Series, 1987	1	1	1	201*	1	0

Highest finite batting average:

Player	Ave	Series	Matches	Inns	NO	HS	100	50
WR Hammond (ENG)	563.0	England in New Zealand Test Series, 1932/33	2	2	1	336*	2	0
HM Amla (SA)	490.0	South Africa in India Test Series, 2009/10	2	3	2	253*	3	0
DA Warner (AUS)	489.0	Pakistan in Australia Test Series, 2019/20	2	2	1	335*	2	0
R Dravid (INDIA)	432.0	Zimbabwe in India Test Series, 2000/01	2	3	2	200*	2	1
KC Sangakkara (SL)	428.0	Bangladesh in Sri Lanka Test Series, 2007	3	3	2	222*	2	0
DJ Cullinan (SA)	427.0	South Africa in New Zealand Test Series, 1998/99	3	3	2	275*	2	0
HP Tillakaratne (SL)	403.0	West Indies in Sri Lanka Test Series, 2001/02	3	4	3	204*	2	1
SR Waugh (AUS)	362.0	Sri Lanka in Australia Test Series, 1995/96	2	3	2	170	2	1
S Chanderpaul (WI)	354.0	West Indies in Bangladesh Test Series, 2012/13	2	3	2	203*	2	0
IR Bell (ENG)	331.0	Sri Lanka in England Test Series, 2011	3	4	3	119*	2	2
Inzamam-ul-Haq (PAK)	329.0	New Zealand in Pakistan Test Series, 2002	1	1	0	329	1	0
Younis Khan (PAK)	313.0	Sri Lanka in Pakistan Test Series, 2008/09	2	1	0	313	1	0
RR Sarwan (WI)	301.0	Bangladesh in West Indies Test Series, 2004	2	2	1	261*	1	0

Five or more innings in a series scoring 50+ each time:

Player	Inns	Series	Matches	NO	Runs	HS	Ave	100	50
KD Walters (AUS)	6	The Frank Worrell Trophy (West Indies in Australia), 1968/69	4	0	699	242	116.50	4	2
GS Sobers (WI)	5	West Indies in India Test Series, 1966/67	3	2	342	95	114.00	0	5
S Chanderpaul (WI)	5	The Wisden Trophy (West Indies in England), 2007	3	2	446	136*	148.66	2	3
MA Taylor (AUS)	5	Pakistan in Australia Test Series, 1989/90	3	1	390	101*	97.50	2	3
Mohammad Yousuf (PAK)	5	West Indies in Pakistan Test Series, 2006/07	3	0	665	192	133.00	4	1
CH Lloyd (WI)	5	The Wisden Trophy (England in West Indies), 1980/81	4	0	383	100	76.60	1	4
Inzamam-ul-Haq (PAK)	5	England in Pakistan Test Series, 2005/06	3	1	431	109	107.75	2	3

Taking 5+ wickets each time in 3 or more innings of a series:

Player	Inns	Series	Matches	Wkts	Ave	SR	BBI	BBM	5	10
CTB Turner (AUS)	4	The Ashes (Australia in England), 1888	3	21	12.42	31.2	6/112	10/63	4	1
Saqlain Mushtaq (PAK)	4	Pakistan in India Test Series, 1998/99	2	20	20.15	44.9	5/93	10/187	4	2

Averaging at least 50 with the bat and at most 20 with the ball (min 100 runs, 15 wickets):

Player	Series	Matches	BatInns	Runs	BatAve	BowlInns	Wkts	BowlAve
Imran Khan (PAK)	India in Pakistan Test Series, 1982/83	6	5	247	61.75	10	40	13.95
SCJ Broad (ENG)	Pataudi Trophy (India in England), 2011	4	4	182	60.66	8	25	13.84
H Verity (ENG)	England in India Test Series, 1933/34	3	3	121	60.50	6	23	16.82
Imran Khan (PAK)	Pakistan in England Test Series, 1982	3	5	212	53.00	6	21	18.57
W Barnes (ENG)	The Ashes (England in Australia), 1884/85	5	8	369	52.71	7	19	15.36
IT Botham (ENG)	England in New Zealand Test Series, 1977/78	3	5	212	53.00	6	17	18.29
JH Kallis (SA)	West Indies in South Africa Test Series, 1998/99	5	10	485	69.28	10	17	17.58
CL Cairns (NZ)	West Indies in New Zealand Test Series, 1999/00	2	2	103	51.50	4	17	9.94
TT Bresnan (ENG)	Pataudi Trophy (India in England), 2011	3	3	154	77.00	6	16	16.31
JM Gregory (AUS)	Australia in South Africa Test Series, 1921/22	3	4	205	51.25	6	15	18.93
MG Bevan (AUS)	The Frank Worrell Trophy (West Indies in Australia), 1996/97	4	7	275	55.00	6	15	17.66

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December 31, 2021

Calculating the locations of stars in the sky

Filed under: geography,mathematics,science — ckrao @ 10:09 am

We present here a calculation of the location of a star as a function of its declination, the observer’s latitude and time after it is at its highest position in the sky. We use the fact that stars trace out circular paths about a fixed point in the sky.

The image below shows a celestial sphere centred on an observer at the location $O$ . Assume the observer is in the northern hemisphere and the point $A$ represents the north celestial pole about which the stars appear to rotate anti-clockwise as the earth rotates on its axis (in the southern hemisphere stars rotate clockwise about the south celestial pole). The red ellipse illustrates the circular path of a star over a 24-hour period – point $B$ is its highest location while point $C$ is where it will be after a quarter of a day. Also shown in the diagram are axes $OA$ (pointing east), $OY$ (pointing north), $OZ$ (pointing directly overhead) and corresponding unit basis vectors $\mathbf{i}$ , $\mathbf{j}$ and $\mathbf{k}$ .

Our aim is to find the location of the star (in 3-dimensional coordinates) on the red circle given:

$t$ – the time (as a proportion of a day) after the star has reached its highest point
$\delta$ – the angle of declination of the star (-90° to 90°) – the angle between the star and the celestial equator (which is the earth’s equator projected skyward)
$\phi$ – the latitude of the observer (-90° to 90°)

The point $A$ is fixed as the earth rotates and in the north direction with an angle of elevation equal to the location’s latitude. Hence we may write

$\displaystyle \vec{OA} = 0\ \mathbf{i} + \cos \phi\ \mathbf{j} + \sin \phi\ \mathbf{k}.\quad\quad ...(1)$

Next consider the angle between $OA$ and $OB$ . If $\delta = 90^{\circ}$ , we would have a northern pole star and $\angle AOB = 0^{\circ}$ . If $\delta = 0^{\circ}$ we would have a star on the celestial equator and $\angle AOB = 90^{\circ}$ . More generally,

$\displaystyle \angle AOB = 90^{\circ}-\delta. \quad\quad ...(2)$

The point $B$ has an angle of elevation of $\phi + 90^{\circ}-\delta$ , hence we have

$\displaystyle \begin{aligned}\vec{OB} &= 0\ \mathbf{i} + \cos (\phi + 90^{\circ}-\delta ) \mathbf{j} + \sin (\phi + 90^{\circ}-\delta ) \mathbf{k}\\ &= \sin (\delta - \phi ) \mathbf{j} + \cos (\delta - \phi ) \mathbf{k}. \quad \quad ...(3)\end{aligned}$

The circular path of the star can be regarded as a point traced around by a line having fixed angle $(90^{\circ}-\delta)$ from the fixed line $OA$ . This circle has its centre at the point $A^{'}$ which is the projection of $OB$ onto the segment $OA$ . Note that $A^{'}$ does not lie on the sphere but $A$ , $B$ and $C$ do. We have

$\displaystyle \vec{OA^{'}} = \cos (90^{\circ}-\delta) \vec{OA} = \sin \delta \quad\quad ...(4)$

and

$\displaystyle |\vec{A^{'}B}| = \cos \delta.\quad\quad ...(5)$

We parameterise any point on this circular path by expressing it in terms of the basis vectors $\vec{A^{'}B}$ and $\vec{A^{'}C}$ . For any point $P$ on the path we can write

$\displaystyle \vec{A^{'}P} = \cos 2\pi t\ \vec{A^{'}B} + \sin 2 \pi t\ \vec{A^{'}C}, \quad t \in [0, 1].\quad\quad ...(6)$

For example,

if $t = 0$ , $\vec{A^{'}P} = \vec{A^{'}B}$
if $t = 0.25$ , $\vec{A^{'}P} = \vec{A^{'}C}$
if $t = 0.5$ , $\vec{A^{'}P} = -\vec{A^{'}B}$
if $t = 0.75$ , $\vec{A^{'}P} = -\vec{A^{'}C}$

Since $A^{'}C$ has the same length as $|\vec{A^{'}B}|$ and is pointing directly west (i.e. perpendicular to both $\vec{OA}$ and $\vec{OB}$ ), we have from (5):

$\vec{A^{'}C} = -\cos \delta\ \mathbf{i}.\quad\quad ...(7)$

We now have all the ingredients we need to find $\vec{OP}$ :

$\displaystyle\begin{aligned}\vec{OP} &= \vec{OA^{'}} + \vec{A^{'}P}\\&= \vec{OA^{'}} + \cos 2\pi t\ \vec{A^{'}B} + \sin 2 \pi t\ \vec{A^{'}C}\quad \text{(by (6))}\\&=\vec{OA^{'}} + \cos 2\pi t\ (\vec{A^{'}O} + \vec{OB}) + \sin 2 \pi t\ \vec{A^{'}C}\\&= \vec{OA^{'}} - \cos 2\pi t\ \vec{OA^{'}} + \cos 2\pi t\ \vec{OB} + \sin 2 \pi t\ \vec{A^{'}C}\\&= (1- \cos 2\pi t) \vec{OA^{'}} + \cos 2\pi t\ \vec{OB} + \sin 2 \pi t\ \vec{A^{'}C}\\&=\left(1 - \cos 2\pi t \right)\sin \delta\ \vec{OA} + \cos 2\pi t\ \vec{OB} + \sin 2 \pi t\ \vec{A^{'}C}\quad\text{(by (4))}\\&=\left(1 - \cos 2\pi t \right)\sin \delta \left(\cos \phi\ \mathbf{j} + \sin \phi\ \mathbf{k}\right) + \cos 2\pi t \left(\sin (\delta - \phi) \mathbf{j} + \cos (\delta - \phi) \mathbf{k} \right)\\&\quad\quad + \sin 2 \pi t \left(-\cos \delta\ \mathbf{i} \right)\quad\text{(by (1), (3) and (7))}\\&=-\sin 2\pi t \cos \delta\ \mathbf{i} + \left(\sin \delta \cos \phi + \cos 2\pi t \left( \sin (\delta - \phi ) - \sin \delta \cos \phi \right) \right) \mathbf{j}\\&\quad\quad + \left( \sin \delta \sin \phi + \cos 2 \pi t \left( \cos (\delta - \phi ) - \sin \delta \sin \phi \right) \right) \mathbf{k}\\&=-\sin 2\pi t \cos \delta\ \mathbf{i} + \left( \sin \delta \cos \phi - \cos 2\pi t \cos \delta \sin \phi \right) \mathbf{j}\\&\quad\quad + \left(\sin \delta \sin \phi + \cos 2 \pi t \cos \delta \cos \phi \right) \mathbf{k}\quad\text{(using trigonometric identities).}\quad\quad ...(8)\end{aligned}$

In this formula, the angle of elevation $\theta$ is found by setting $\sin \theta$ equal to the $\mathbf{k}$ -component, or

$\displaystyle \theta = \arcsin \left(\sin \delta \sin \phi + \cos 2 \pi t \cos \delta \cos \phi \right).\quad \quad ...(9)$

Let us test out formula (8) in some special cases:

If $\delta = 90^{\circ}$ we recover the formula $\vec{OP} = \cos \phi\ \mathbf{j} + \sin \phi\ \mathbf{k} = \vec{OA}$ , the fixed location of the pole star.
If $\delta = 0^{\circ}$ we recover the formula $\vec{OP} = -\sin 2 \pi t\ \mathbf{i} - \cos 2\pi t \left(\sin \phi\ \mathbf{j} - \cos \phi\ \mathbf{k} \right)$ . This traces a circle with diameter joining $-\sin \phi \ \mathbf{j} + \cos \phi\ \mathbf{k}$ and $\sin \phi \ \mathbf{j} - \cos \phi\ \mathbf{k}$ (two antipodal points), hence it is a great circle on the celestial sphere.
If $\phi = 0^{\circ}$ (observer on the equator) we obtain $\vec{OP} = -\sin 2\pi t \cos \delta\ \mathbf{i} + \sin \delta \mathbf{j} + \cos 2 \pi t \cos \delta\ \mathbf{k}$ , hence the $\mathbf{j}$ -component remains fixed and a circular path is traced.
If $\phi = 90^{\circ}$ (observer at the north pole) we obtain $\vec{OP} = -\sin 2\pi t \cos \delta\ \mathbf{i} - \cos 2\pi t \cos \delta\ \mathbf{j} + \sin \delta\ \mathbf{k}$ , hence the star traces out a circle with constant angle of elevation.

We can also determine the times at which a star rises or sets by setting the $\mathbf{k}$ -component of position in (8) to 0:

$\displaystyle \begin{aligned} \sin \delta \sin \phi + \cos 2 \pi t \cos \delta \cos \phi &= 0\\ \Rightarrow \quad \cos 2 \pi t &= -\frac{\sin \delta \sin \phi }{\cos \delta \cos \phi }\\&= -\tan \delta \tan \phi.\quad \quad ...(9)\end{aligned}$

This is the so-called sunrise equation and was derived differently in an earlier blog post in [1].

Next let us look at the case when the star is our sun. The declination changes during the year between -23.4° and +23.4° (earth’s axial tilt) between the winter and summer soltice (for the northern hemisphere) as the earth revolves around the sun. Assume that the centre of the sun is at the origin and that earth’s orbit is the x-y plane having the form $r = R(\cos 2 \pi s\ \mathbf{i} + \sin 2\pi s\ \mathbf{j})$ (assuming a circular orbit with radius $R$ starting at $R\ \mathbf{i}$ at $s=0$ ). The parameter $s$ here represents the fraction of year after the winter solstice. Earth’s axis of rotation points in the direction $a = \sin 22.4^{\circ}\ \mathbf{i} + \cos 22.4^{\circ}\ \mathbf{k}$ , being tilted away from the sun in the north when $s = 0$ .

From the earth’s point of view the sun is in the direction $-\hat{r} = -(\cos 2 \pi s\ \mathbf{i} + \sin 2\pi s\ \mathbf{j})$ . Then the angle $(90 - \delta)$ between the sun’s position and the earth’s axis satisfies

$\displaystyle \begin{aligned}\sin \delta = \cos (90 - \delta) &= -\hat{r} . a\\&= -(\cos 2 \pi s\ \mathbf{i} + \sin 2\pi s\ \mathbf{j}).(\sin 22.4^{\circ}\ \mathbf{i} + \cos 22.4^{\circ}\ \mathbf{k})\\&= -\sin 22.4^{\circ}\cos 2 \pi s\\ \Rightarrow \delta &= \arcsin (-\sin 22.4^{\circ}\cos 2 \pi s)\\ &\approx \arcsin(-0.398 \cos 2 \pi s).\quad\quad ...(10) \end{aligned}$

For example if $s = 0$ , we have $\delta = -22.4^{\circ}$ . If $s = 0.25, 0.75$ , we have the equinoxes and $\delta = 0^{\circ}$ . Finally if $s = 0.5$ then $\delta = 22.4^{\circ}$ .

Substituting (10) into (8) gives the location of the sun given the time of year and time relative to when it’s at its highest point in the sky (solar noon). Note that the equation is not perfect since it does not take into account atmospheric refraction or the fact that the earth’s orbit is not perfectly circular and therefore the earth is not uniform in speed. For more exercises on the length of days based on latitude and the sun’s angle of declination refer to [2].

Finally, we can determine the bearing of a star when it rises or sets in the following manner. The position $P$ of the sun is in the x-y plane and so has the form

$\displaystyle \vec{OP} = x\ \mathbf{i} + y\ \mathbf{j}.\quad\quad ...(11)$

Secondly $\angle POA = 90^{\circ} - \delta$ and hence

$\displaystyle \begin{aligned}\sin \delta &= \cos (90^{\circ} - \delta)\\ &= \vec{OP}.\vec{OA}\quad \text{(the dot product of two unit vectors is cosine of the angle between them)}\\ &= (x\ \mathbf{i} + y\ \mathbf{j}).(\cos \phi\ \mathbf{j} + \sin \phi\ \mathbf{k})\quad\quad\text{(from (1) and (11))}\\&=y \cos \phi.\quad\quad ...(12)\end{aligned}$

Hence $y = \sin \delta/\cos \phi$ . For example taking the sun on the summer solstice at Melbourne, Australia we have $\delta = -22.4^{\circ}$ , $\phi = -38^{\circ}$ and so $y = \sin (-22.4^{\circ})/\cos(-38^{\circ}) \approx -0.484$ . This corresponds to a bearing of $\arcsin(0.484) + 90^{\circ} \approx 119^{\circ}$ , around 20 degrees south of east. The answer given in timeanddate.com is $121^{\circ}$ , slightly more perhaps because it takes into account refraction and the fact that the sun is not pointlike.

Reference

[1] The Shortest Day of the Year, Chaitanya’s Random Pages – https://ckrao.wordpress.com/2012/06/23/the-shortest-day-of-the-year/

[2] Alan Champneys, The Length of Days – https://www.bristol.ac.uk/media-library/sites/engineering/engineering-mathematics/documents/modelling/teacher/daylength_t.pdf

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September 24, 2021

International men’s cricket match streaks

Filed under: Uncategorized — ckrao @ 8:58 am
Tags: cricket, sport

I have created a few interactive charts with Tableau on winning/losing/drawing international men’s cricket streaks using data from ESPNcricinfo.com’s Statsguru. You can click on any of the links or graphs to interact with it in a new page.

1. Most consecutive tests played with N matches of a given result (won/lost/drawn)

2. Fewest consecutive tests played with N matches of a given result (won/lost/drawn)

3. Most consecutive one-day internationals played with N matches of a given result (won/lost/drawn)

4. Fewest consecutive one-day internationals played with N matches of a given result (won/lost/drawn)

5. Most consecutive T20 internationals played with N matches of a given result (won/lost/drawn)

6. Fewest consecutive T20 internationals played with N matches of a given result (won/lost/drawn)

Here are a few observations.

Tests:

Largely due to timeless tests in Australia up to World War II, Australia had 0 drawn tests at home Australia for 87 consecutive tests until 1946. For similar reasons England had 0 drawn tests away from home for 66 consecutive tests up to 1914 when they drew in South Africa.
The top streaks without a loss for any team anywhere are 27, 26 and 25 by West Indies (1982-84), England (1968-71) and Australia (1946-51) respectively.
England amazingly lost only 1 test away from home in 40 matches between 1963 and 1972.
At home Pakistan lost only 1 test out of 40 from 1969 to 1986 while India only lost once in a span of 35 tests between 2012 and 2019.
West Indies lost only 2 out of 53 tests between 1980 and 1986 and just 10 out of 100 from 1976 to 1988.
Australia won 12 consecutive tests at home between 1999 and 2001 and 49 out of 61 home tests between 1998 and 2008. India is not far behind with 40 out of 53 home test wins from 2010 to 2021.
In any ground Australia won 76 out of 100 tests between 1999 and 2008.
South Africa has played 32 consecutive matches (anywhere) without a draw from 2017, an active streak. The next best is 26 by Zimbabwe from 2005 to 2017.
New Zealand has an impressive active streak of 17 matches without a loss dating back to 2017 with 8 of their 13 wins by an innings.

One-day Internationals:

Australia lost just 2 matches out of 32 anywhere between 2002 and 2003.
India lost only 1 match out of 16 away from home between 2016 and 2018.
West Indies lost only 7 matches out of 50 in away or neutral grounds between 1981 and 1985.
Four teams have won 16 consecutive ODIs at home – Australia (2014-16), South Africa (2016-17), Sri Lanka (1996-98) and West Indies (1986-90). The best is 18 by Australia and Sri Lanka.
Australia (1999-2004), Sri Lanka (1994-2004) and South Africa (1994-2001) all won 53/65 matches at home.

T20 Internationals:

Afghanistan and Romania share the record of consecutive wins (12).
Zimbabwe had 16 consecutive losses (2010-13).
Afghanistan (2016-19) and Pakistan (2017-18) have both won 23 out of 26 consecutive games.
Afghanistan won 40 out of 50 matches (2014-19).

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December 30, 2020

An identity involving the product of reciprocals

Filed under: mathematics — ckrao @ 10:18 am

In this post I would like to prove the following identity, motivated by this tweet.

$\displaystyle n! \prod_{k=0}^n \frac{1}{x+k} = \frac{1}{x\binom{x+n}{n}} = \sum_{k=0}^n \frac{(-1)^k \binom{n}{k}}{x+k}$

The first of these equalities is straightforward by the definition of binomial coefficients. To prove the second, we make use of partial fractions. We write the expansion

$\displaystyle \prod_{k=0}^n \frac{1}{x+k} = \sum_{k=0}^n \frac{A_k}{x+k},$

where the coefficients $A_k$ are to be determined. Multiplying both sides by $(x+k')$ for some $k' \in \{0, 1, \ldots, n\}$ ,

$\displaystyle \begin{aligned} (x+k') \prod_{k=0}^n \frac{1}{x+k} &= \sum_{k=0}^n \frac{A_k(x+k')}{x+k}\\\hbox{i.e.}\quad \prod_{\substack{k=0\\k \neq k'}}^n \frac{1}{x+k} &= A_{k'} + \sum_{\substack{k=0\\k \neq k'}}^n \frac{A_k(x+k')}{x+k}.\end{aligned}$

Then setting $x = -k$ in both sides gives

$\displaystyle \begin{aligned} \prod_{\substack{k=0\\k \neq k'}}^n \frac{1}{k-k'} &= A_{k'} + \sum_{\substack{k=0\\k \neq k'}}^n \frac{A_k(0)}{x+k}\\&= A_{k'}\\\hbox{i.e.}\quad A_{k'} &= \frac{1}{-k'} \cdot \frac{1}{-k'+1}\cdot \ldots \cdot \frac{1}{-1} \cdot \frac{1}{1}\cdot \frac{1}{2}\cdot \ldots \cdot \frac{1}{n-k'}\\&= \frac{(-1)^{k'}}{k'! (n-k')!}\\&= \frac{(-1)^{k'}}{n!} \binom{n}{k'},\end{aligned}$

leading to the desired result.

As a few examples of this identity we have:

$\displaystyle \begin{aligned}n=1&:& \frac{1}{x(x+1)} &= \frac{1}{x} - \frac{1}{x+1}\\n = 2&:& \frac{1}{x(x+1)(x+2)} &= \frac{1}{2} \left[ \frac{1}{x} - \frac{2}{x+1} + \frac{1}{x+2} \right]\\n=3&:& \frac{1}{x(x+1)(x+2)(x+3)} &= \frac{1}{6} \left[ \frac{1}{x} - \frac{3}{x+1} + \frac{3}{x+2} - \frac{1}{x+3}\right] \end{aligned}$

I had previously posted an identity with similar, but trickier derivation here.

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July 12, 2020

Charting Test and ODI cricket performances over consecutive innings

Filed under: cricket,sport — ckrao @ 2:23 am

Adding to my earlier blog post about the highest proportion of test scores above m after n innings, I have created some new interactive charts for best streaks early and mid-career in both bowling and batting in tests and ODIs. The data is mostly from https://data.world/cclayford/cricinfo-statsguru-data.

1. Test batting

2. Test bowling

3. ODI batting

4. ODI bowling

Below are shown a few sample charts. Clicking on the chart will take you to a new page where you can interact further.

Test batting:

Two players had a batting average over 100 after 10 test innings

A player’s stats can be viewed by opposition.

Test bowling:

Jason Holder has had an all-time great low bowling average over 20 consecutive innings, Steve Waugh also features here.

Early players dominate the list of fastest to 5 6-wicket hauls in tests.

ODI batting:

Kohli averaged almost 70 per innings over 50 consecutive innings, Warner also has also done very well from 2016-2019.

Shahid Afridi’s maintained this high a batting strike rate over 50 innings between 2004 and 2007.

ODI bowling:

Rashid Khan took 11 more wickets than the next best over 30 consecutive innings.

Over 100 ODI innings, Muralitharan averaged more than 2 better than the next best.

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July 8, 2020

The largest parallelogram in a triangle

Filed under: mathematics — ckrao @ 11:59 pm

In this post we find the largest parallelogram, rhombus, rectangle and square that can be contained in a given triangle. We will see that in the first three cases we can achieve half the area of the triangle but no more, while it is generally less than this for a square.

Inscribing a parallelogram, rhombus, rectangle and square of maximum area in a triangle

1. The largest parallelogram inside a triangle

It can be readily seen that one can obtain a parallelogram having half the area of a triangle by connecting a vertex with the three midpoints of the sides. (This has half the base length of the triangle and half its height.)

Is it possible to obtain a larger parallelogram? As outlined in [1], if two or fewer vertices of the parallelogram are on sides of the triangle, a smaller similar triangle can be created by drawing a line parallel to the triangle’s side through a vertex of the parallelogram that is interior triangle. (This is done three times in the figure below.) This reduces the problem to the next case.

A smaller similar triangle containing the parallelogram can be created by lines through its vertices parallel to the sides of the triangle

We are left to consider the case where three or more vertices of the parallelogram on the triangle. We can draw a line from a vertex to the opposite side parallel to a pair of sides (in the figure below $AH$ is drawn parallel to $DG$ ), thus dissecting the triangle into two. Each of the smaller triangles then has an inscribed parallelogram where two of the vertices are on a side of each triangle. Then by drawing lines parallel to sides if required, we create two sub-problems each having four vertices of the parallelogram on the sides of the triangle.

Dissecting a triangle so that each smaller triangle has a parallelogram with two vertices on a side. The right parallelogram is contained in a larger one $HIEJ$ formed by lines parallel to the sides.

Dissecting a triangle so that each smaller triangle has a parallelogram with two vertices on a side. The right parallelogram is contained in a larger one $HIEJ$ formed by lines parallel to the sides.

Finally, if all four vertices of the parallelogram are on sides of the triangle, by the pigeonhole principle, two of them are on a side (say $BC$ as shown in the figure below). In this figure, if we let $AD/AB = k$ and the height of ABC from $BC$ be $h_a$ , then by the similarity of triangles $ADE$ and $ABC$ , $DE = k.BC$ and $\triangle ADE$ has height $kh_a$ . Then the area of the parallelogram $DEFG$ is $DE \times (1-k)h_a = k(1-k) DE.h_a$ which is $2k(1-k)$ times the area of $\triangle ABC$ . This quantity has maximum value 1/2 when $k=1/2$ so we conclude that the parallelogram does not exceed half the triangle’s area.

A parallelogram with all four vertices on sides of a triangle must have two of them on one side.

2. The largest rhombus in a triangle

Constraining sides of the parallelogram to be equal (forming a rhombus), we claim that the largest rhombus that can be inscribed in a triangle is also half its area. This can be formed with two of the vertices on the second longest side of the triangle. Suppose $a \geq b \geq c$ are the sides of the triangle with $b=AC$ the second longest side length. Then let the segment $MN$ joining the midpoints of $AB$ and $BC$ form one side of the rhombus of length $b/2$ . It remains to be shown that there exist parallel segments of this same length from $M, N$ to $AC$ . The longest possible such segment has length $NC = a/2$ and the shortest has length $h_b/2$ , half the length of the altitude of $\triangle ABC$ from $B$ . We wish to show that $h_b/2 \leq b/2 \leq a/2$ . This follows from

$\displaystyle h_b = c \sin A \leq c \leq b \leq a.$

Inscribing a rhombus of maximal area in a triangle

The area of this rhombus is clearly half the area of the triangle as it has half the length of its base and half the height.

3. The largest rectangle in a triangle

Here if $BC$ is the longest side of the triangle we form the rectangle from midpoints $D, E$ of $AB$ and $AC$ respectively, dropping perpendiculars onto $BC$ forming rectangle $DEFG$ :

The largest rectangle inscribed in a triangle, where D and E are midpoints

The area of this rectangle is half the area of the triangle as it has half the length of its base and half the height.

Interestingly the reflections of the vertices of the triangle in the sides of the rectangle coincide, showing a paper folding interpretation of this result [2].

Reflecting A, B and C in DE, DG and EF respectively yields the same image, yielding a paper folding interpretation

Since rhombuses and rectangles are special cases of parallelograms and we found that inscribed parallelograms in a triangle occupy no more than half its area, the rhombus and rectangle constructions here are optimal.

4. The largest square in a triangle

Here we shall see that the best we can do may not be half the area of the triangle. As before, if two or fewer vertices of the square are not on the sides of the triangle it is possible to scale up the square (or scale down the triangle) so that three of the square’s vertices are on the sides. We claim that the largest square must have two of its vertices on a side of the triangle. Suppose this is not the case and we have the figure below.

Squares with a vertex on each side of $\triangle ABC$ pivot about the point $P$

Consider squares $LMNO$ inscribed in $\triangle ABC$ so that one vertex $L$ is on $AB$ , $M$ is on $BC$ and $O$ is on $CA$ . We claim that the largest such square is either $DEFG$ (two vertices on $BC$ ) or $HIJK$ (two vertices on $AC$ ). Suppose on the contrary that neither of these squares is the largest. Then we make use of the fact that all 90-45-45 triangles $LMO$ inscribed in $\triangle ABC$ have a common pivot point $P$ . This is the point at the intersection of the circumcircles of triangles $OAL$ , $LBM$ and $MCO$ . To show these circles intersect at a single point, we can prove that if the circumcircles of triangles $OAL$ and $LBM$ intersect at $P$ then the points $O,P,M,C$ are cyclic by the following equality:

$\displaystyle \begin{aligned} \angle MPO &= 360^{\circ} - \angle LPM - \angle OPL\\ &= (180^{\circ} - \angle LPM) + (180^{\circ} - \angle OPL)\\ &= \angle B + \angle A \\ &= 180^{\circ} - \angle C,\end{aligned}$

where the second last equality makes use of quadrilaterals $BMPL$ , $ALPO$ being cyclic.

Additionally we have

$\displaystyle \begin{aligned}\angle BPC &= \angle BPM + \angle MPC\\ &= \angle BLM + \angle MOC\\ &= (\angle LAM + \angle AML) + (\angle MAO + \angle OMA)\\&=(\angle LAM + \angle MAO ) + (\angle AML + \angle OMA )\\&= \angle BAC + \angle OML\\&=\angle A + 45^{\circ}, \end{aligned}$

with similar relations for $\angle APB$ and $\angle CPA$ . Hence $P$ is the unique point satisfying

$\displaystyle \begin{aligned}\angle APB &= \angle ACB + 90^{\circ}\\\angle BPC &= \angle BAC + 45^{\circ}\\\angle CPA &= \angle CBA +45^{\circ}.\end{aligned}$

(Each equation defines a circular arc, they intersect at a single point. Note that $P$ may be outside triangle $ABC$ .) This point is the centre of spiral similarity of 90-45-45 triangles $LMO$ with $L, M, O$ respectively on the sides $AB, BC, CA$ of the triangle. Consider the locus of the points of the square as $L, M, O$ vary on straight line segments pivoting about $P$ . It follows that the fourth point of the square $N$ also traces a line segment, between the points $F$ and $J$ so as to be contained within the triangle.

As the side length of the square is proportional to the distance of a vertex to its pivot point, the largest square will be where $NP$ is maximised. We have seen that the point $N$ varies along a line segment, so $NP$ will be maximised at one of the extreme points – either when $N=F$ or $N=J$ . We therefore conclude that the largest square inside a triangle will have two points on a side.

If the triangle is acute-angled, by calculating double the area of the triangle in two ways, the side length $x$ of a square on the side of length $a$ with altitude $h_a$ is derived as

$\displaystyle \begin{aligned}ah_a &= 2x^2 + (a-x)x + x(h_a-x)\\&=2x^2 + ax - x^2 + xh_a - x^2\\&= ax + xh_a\\Rightarrow \quad x &= \frac{ah_a}{a + h_a}.\end{aligned}$

If the triangle is obtuse-angled, the square erected on a side may not touch both of the other two sides. In the figure below the side length of square $BDEF$ is the same as if $A$ were moved to $G$ , where $\triangle GBC$ is right-angled. In this case the square’s side length is $BC.BG/(BC + BG)$ .

The square erected on side $AC$ when $\angle ABC$ is obtuse

The largest square erected on a side may be constructed using the following beautiful construction [2]: simply erect a square CBDE external to the side $BC$ and find the intersection points $F = AD \cap BC, G = AE \cap BC$ .

These points define the base of the square to be inscribed since by similar triangles

$\displaystyle \frac{IF}{BD} = \frac{AF}{AD} = \frac{FG}{DE} = h_a/(a + h_a)$

so that

$\displaystyle IF = FG = \frac{ah_a}{a + h_a}.$

One can use this interactive demo to view the largest square in any given triangle. One needs to find the largest of the three possibilities of the largest square erected on each side. In the acute-angled-triangle case, the largest square is on the side that minimises the sum of that side length and its corresponding perpendicular height – as their product is fixed as twice the triangle’s area, this will occur when the side and height have minimal difference. For a right-angled triangle with legs $a, b$ and hypotenuse $c$ , we wish to compare the quantities $(a+b)$ and $(c+h)$ , the two possible sums of the base and height of the triangle. We always have $a + b - c = 2(s-c) = 2r < h$ because the diameter of the incircle of the triangle is shorter than the altitude from the hypotenuse (i.e. the incircle is inside the triangle). We conclude that the largest square in a right-angled triangle is constructed on its two legs rather than its hypotenuse.

References

[1] I. Niven, Maxima and Minima without Calculus, The Mathematical Association of America, 1981.

[2] M. Gardner, Some Surprising Theorems About Rectangles in Triangles, Math Horizons, Vol. 5, No. 1 (September 1997), pp. 18-22.

[3] Jaime Rangel-Mondragon “Largest Square inside a Triangle” http://demonstrations.wolfram.com/LargestSquareInsideATriangle/ Wolfram Demonstrations Project Published: March 7 2011

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April 16, 2020

Highest proportion of test scores above m after n innings

Filed under: cricket,sport — ckrao @ 6:02 am

I created an interactive workbook with Tableau to determine the test batsmen who have had the highest proportion of innings scoring at least m runs after having played n test innings. Below are some screenshots for particular choices of m runs. The data is available from [1]. As expected Bradman comes up on top in many scenarios but it is interesting to see other names that appear up there.

(Click on the above image to go to the Tableau page if you wish to change the parameters. You can also select the “Innings by innings” tab to look up a player’s list of innings.)

Below we some examples for different m (full-career stats among players who have played at least 20 innings).

m=1: A total of 22 players have had an entire career of 20+ innings getting off the mark each time, with RA Duff (Australia, 1902-1905) the only to play 40 innings (note that JW Burke played 44 innings without a duck, but made 0 not out in one innings).

Angelo Mathews (SL) has managed just 2 ducks in his 154 innings to date.

1 or more

m=10: Hobbs, Hutton, Kanhai and Sobers stand out here, having played over 100 innings and reaching double figures at least 80% of the time (Hobbs over 86%). Labuschagne, Hetmyer, Handscomb and Head are recent players to feature highly here.
10 or more

m=25: Bradman starts to distance himself from the rest. Hammond, Smith, Sobers and de Villiers also impress here.
25 or more

m=50: Smith has matched Barrington’s career figures of 50+ starts. Sutcliffe had 33 50+ scores in his first 64 innings, the same as Bradman.
50 or more

m=75: Barrington’s numbers are amazing here and Katich is ahead of Kohli, Tendulkar and Lara.
75 or more

m=100: Smith and Kohli are currently higher than Sangakkara, the highest among recent retirees.
100 or more

m=125: Only Bradman (6) had more 140+ scores than Labuschagne after playing 23 test innings, equal with Graeme Smith (who had 4 150+ scores in his first 17 innings!).
125 or more

m=150: Bradman is so far ahead of the rest here. Lara and Sangakkara are just one behind Tendulkar with the most 150+ scores despite almost 100 fewer innings.
150 or more

m=175: Again Lara and Sangakkara have the same number of 175+ scores (15).
175 or more

m=200: Kohli is similar to Hammond’s career figures at this stage, with 6 of his 7 double centuries coming within 33 innings between July 2016 and December 2017.
200 or more

Please leave any other interesting observations in the comments.

Reference

[1] https://data.world/cclayford/cricinfo-statsguru-data

Comments (7)

December 7, 2019

Coordinates of special points of the 3-4-5 triangle

Filed under: mathematics — ckrao @ 3:40 am

One thing I observed is that the 3-4-5 triangle is rather attractive in solving problems using coordinates. If the vertices are placed at (0,3), (0,0) and (4,0) the following are the coordinates of points and equations of some lines of interest.

Line AC: $x/4 + y/3 = 1$

Incentre: $(1, 1)$

Centroid: $(4/3, 1)$

Circumcentre: $(2, 1.5)$

Orthocentre: $(0, 0)$

Nine-point centre: $(1, 3/4)$ (midpoint of the midpoints of AB and BC)

Angle bisectors: $y = x, y=-2x +3, y=4/3-x/3$

Ex-centres (intersection of internal and external bisectors): $(3,- 3), (6, 6), (-2, 2)$

3-4-5

Lines joining the excentres (in red above): $y=-x, y=x/2 +3, y = 3(x-4)$

Altitude to the hypotenuse: $y = 4x/3$

Euler line: $y=3x/4$

Foot of altitude to the hypotenuse: $(36/25, 48/25)$ (where $x/4 + y/3 = 1$ intersects $y=4x/3$ )

Symmedian point (midpoint of the altitude to the hypotenuse [1]): $(18/25, 24/25)$

Contact points of incircle and triangle: $(1,0), (0,1), (8/5, 9/5)$

Gergonne point (intersection of Cevians that pass through the contact points of the incircle and triangle = the intersection of $y=3-3x$ and $y=1-x/4$ ): $(8/11, 9/11)$

Nagel point (intersection of Cevians that pass through the contact points of the ex-circles and triangle = the intersection of $y=3-x$ and $y=2-x/2$ : $(2,1)$

Reference

[1] Weisstein, Eric W. “Symmedian Point.” From MathWorld–A Wolfram Web Resource. http://mathworld.wolfram.com/SymmedianPoint.html

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January 26, 2019

49+ °C temperatures in Australia

Filed under: climate and weather — ckrao @ 12:32 pm

Below is a list of recorded instances of maximum temperatures of 49 degrees Celsius or more in Australia, based on [1] and [2] from Australia’s Bureau of Meteorology. Out of the 48 52 occasions, 22 26 have occurred in this decade including 8 (so far) during this summer alone! I believe all the stations have been recording temperatures for at least 20 years except Port Augusta and Keith West (which both started in 2001). Edited: 20 Dec 2019

Temperature (°C)	Date	Station Name	State
50.7	2-Jan-60	Oodnadatta Airport	SA
50.5	19-Feb-98	Mardie	WA
50.3	3-Jan-60	Oodnadatta Airport	SA
49.9	19-Dec-19	Nullarbor	SA
49.8	19-Dec-19	Eucla	WA
49.8	21-Feb-98	Emu Creek Station	WA
49.8	13-Jan-79	Forrest Aero	WA
49.8	3-Jan-79	Mundrabilla Station	WA
49.7	10-Jan-39	Menindee Post Office	NSW
49.6	12-Jan-13	Moomba Airport	SA
49.5	19-Dec-19	Forrest	WA
49.5	24-Jan-19	Port Augusta Aero	SA
49.5	24-Dec-72	Birdsville Police Station	QLD
49.4	21-Dec-11	Roebourne	WA
49.4	16-Feb-98	Emu Creek Station	WA
49.4	7-Jan-71	Madura Station	WA
49.4	2-Jan-60	Marree Comparison	SA
49.4	2-Jan-60	Whyalla (Norrie)	SA
49.3	27-Dec-18	Marble Bar	WA
49.3	2-Jan-14	Moomba Airport	SA
49.3	9-Jan-39	Kyancutta	SA
49.2	20-Dec-19	Keith West	SA
49.2	24-Jan-19	Kyancutta	SA
49.2	21-Feb-15	Roebourne Aero	WA
49.2	10-Jan-14	Emu Creek Station	WA
49.2	22-Dec-11	Onslow Airport	WA
49.2	1-Jan-10	Onslow	WA
49.2	11-Jan-08	Onslow	WA
49.2	9-Feb-77	Mardie	WA
49.2	1-Jan-60	Oodnadatta Airport	SA
49.2	3-Jan-22	Marble Bar Comparison	WA
49.2	11-Jan-05	Marble Bar Comparison	WA
49.1	24-Jan-19	Tarcoola Aero	SA
49.1	23-Jan-19	Red Rocks Point	WA
49.1	13-Jan-19	Marble Bar	WA
49.1	27-Dec-18	Onslow Airport	WA
49.1	3-Jan-14	Walgett Airport AWS	NSW
49.1	2-Jan-10	Emu Creek Station	WA
49.1	18-Feb-98	Roebourne	WA
49.1	23-Dec-72	Moomba	SA
49	15-Jan-19	Tarcoola Aero	SA
49	23-Jan-15	Marble Bar	WA
49	13-Jan-13	Birdsville Airport	QLD
49	9-Jan-13	Leonora	WA
49	21-Dec-11	Roebourne Aero	WA
49	1-Jan-10	Mardie	WA
49	10-Jan-09	Emu Creek Station	WA
49	11-Jan-08	Port Hedland Airport	WA
49	11-Jan-08	Roebourne	WA
49	12-Jan-88	Marla Police Station	SA
49	6-Dec-81	Birdsville Police Station	QLD
49	22-Dec-72	Marree	SA

References

[1] http://www.bom.gov.au/cgi-bin/climate/extremes/monthly_extremes.cgi

[2] http://www.bom.gov.au/climate/current/statements/scs43e.pdf

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July 5, 2023

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February 15, 2022

Most series playing 5 or more tests:

Most series playing 3 or more tests:

Most series played:

Most series scoring at least r runs:

Most series taking at least w wickets:

Most series scoring at least r runs and taking at least w wickets:

Never batting having played in 3+ tests in a series:

Most consecutive series scoring at least 400 runs:

Most consecutive series taking at least 20 wickets:

Most 50+ scores in a test series:

Most 5-wicket hauls in a series:

Most runs in a series without scoring 50:

Most runs in a series without scoring a century:

Most wickets in a series without 5 in an innings:

Most wickets in a series without 10 in a match:

Most runs scored in a player’s lowest-scoring series:

Most wickets in lowest wicket-taking series:

Most balls bowled in a series without taking a wicket:

Most times the leading run-scorer in a series (both teams):

Most times the leading run-scorer in a series (for their team):

Most times the leading wicket taker in a series (for both teams):

Most times the leading runs scorer in a series (for their team):

Most series playing in at least 3 tests and averaging at least 100 with the bat:

Most series playing at least 3 tests and averaging at most 20 with the ball (minimum 5 wickets):

Lowest bowling strike rate in a series (minimum 10 wickets):

Lowest bowling average in a series (minimum 10 wickets):

Most runs without being dismissed:

Highest finite batting average:

Five or more innings in a series scoring 50+ each time:

Taking 5+ wickets each time in 3 or more innings of a series:

Averaging at least 50 with the bat and at most 20 with the ball (min 100 runs, 15 wickets):

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December 31, 2021

Reference

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September 24, 2021

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December 30, 2020

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July 12, 2020

1. Test batting

2. Test bowling

3. ODI batting

4. ODI bowling

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July 8, 2020

1. The largest parallelogram inside a triangle

2. The largest rhombus in a triangle

3. The largest rectangle in a triangle

4. The largest square in a triangle

References

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April 16, 2020

Reference

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December 7, 2019

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January 26, 2019

References

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