The Number of Rational Points on Elliptic Curves and Circles over Finite Fields

Vol:, No:7, 008 The Number of Rational Points on Elliptic Curves and Circles over Finite Fields Betül Gezer, Ahmet Tekcan, and Osman Bizim International Science Index, Mathematical and Computational Sciences Vol:, No:7, 008 waset.org/publication/178 Abstract In elliptic curve theory, number of rational points on elliptic curves and determination of these points is a fairly important problem. Let p be a prime and be a finite field and k.it is well known that which points the curve y = x 3 + kx has and the number of rational points of on. Consider the circle family x + y = r. It can be interesting to determine common points of these two curve families and to find the number of these common In this work we study this problem. Keywords Elliptic curves over finite fields, rational points on elliptic curves and circles. I. INTRODUCTION Mordell began his famous paper [] with the words Mathematicians have been familiar with very few questions for so long a period with so little accomplished in the way of general results, as that of finding the rational points on elliptic curves. The mathematical theory of elliptic curves was also crucial in the proof of Fermat s Last Theorem in [16]. Let p be a positive integer, be a finite field, F p = \{0} and denote the algebraic closure of with char( ) =, 3. An elliptic curve E over is defined by an equation in the Weierstrass form E : y = x 3 + ax + b, (1) where a, b and a 3 +7b = 0. The discriminant and j invariant of E are defined by and Δ= 16(a 3 +7b ) j = 178(a)3, Δ respectively. We can view an elliptic curve E as a curve in projective plane P, with a homogeneous equation y z = x 3 + axz + bz 3, together with a point at infinity. This point is the point where all vertical lines meet. We denote this point by O. The set of rational points (x, y) on E together with the point O E( )={(x, y) : y = x 3 + ax + b} {O} () is a subgroup of E (for the arithmetic of elliptic curves and rational points on them see [5], [6], [7]). The order of E( ), Betül Gezer, Ahmet Tekcan and Osman Bizim are with the Uludag University, Department of Mathematics, Faculty of Science, Bursa, Turkey (e-mails: betulgezer@uludag.edu.tr, tekcan@uludag.edu.tr, obizim@uludag.edu.tr).this work was supported by The Scientific and Technological Research Council of Turkey. Project no: 107T311. denoted by #E( ), is defined as the number of points on E, and is given by #E( ) = 1+ (( x 3 ) ) + ax + b +1 x x = p +1+ ( x 3 ) + ax + b, (3) where (. ) denotes the Legendre symbol. Let p>3 be a prime and let k F p be a fixed number. In this case, in [6] and [15], the number of rational points on elliptic curves E k : y = x 3 + kx () over is given by the following: 1. If p 3(mod ), then #E( )=p +1.. If p 1(mod ), write p = a +b, where a, b are integers with b is even and a+b 1(mod ), then #E( )=p+1 a if k is a -th power mod p, #E( )=p +1+a if k is a square mod p but not a -th power mod p and #E( )= p +1± b if k is not a square mod p. In [3] and [13], we consider the number of rational points on elliptic curves y = x 3 + b and y = x 3 t x over, respectively. In this paper, we consider the intersection points of the elliptic curves and the circles E k : y = x 3 + kx C r : x + y = r over. It is not difficult to guess that each elliptic curve may not intersect with every circle in the set of rational So, we will take k = p r and in this case, we will determine which elliptic curves and circles have common rational points and what these points are, the number of them and the number of curves and circles which have common rational By equating elliptic curve equation y = x 3 + kx with the circle equation x + y = r, we have the cubic equation x 3 + x + kx r =0. Solving this cubic equation over is the basis of this work. International Scholarly and Scientific Research & Innovation (7) 008 77 scholar.waset.org/1307-689/178

Vol:, No:7, 008 International Science Index, Mathematical and Computational Sciences Vol:, No:7, 008 waset.org/publication/178 II. THE NUMBER OF RATIONAL POINTS ON ELLIPTIC CURVES y = x 3 + kx AND CIRCLES x + y = r OVER. Let p>3 be a prime number and let f(x) =x 3 + a 1 x + a x + a 3, where a 1,a,a 3. Denote the number of solutions of the congruence f(x) 0(mod p) by N p (f(x)). Let P = a 3 1 +9a 1 a 7a 3 Q = (a 1 3a ) 3 D = P Q, 7 where D denotes the discriminant of the cubic polynomial x 3 +a 1 x +a x+a 3. According to Tignol [1], [10], Sun [11], [1], Dickson [] and Skolem [8], [9], we have the following theorem. Theorem.1: If p>3 is a prime, a 1,a,a 3 and p is not divide D, then 0 or 3 if ( D p )=1 N p (f(x)) = 1 if ( D p )= 1 For the cubic congruence, we have 0 if ( D p )=0. x 3 + x + kx r 0(mod p) (5) D = k 3 + k 18kr 7r +r. If we take k and r such that k = p r, then the discriminant of the cubic congruence becomes D = k(k +1) p(36k +7p +). In this case we have, D k(k +1) (mod p). Now we will consider two cases, either p 1(mod ) or p 3(mod ). Let Q p denote the set of quadratic residues modulo p. Case 1. Let p 1(mod ). Since 1 Q p and k r (mod p), wehavek Q p. Therefore k Q p and hence ( D p )=1. By Theorem.1, we know that the cubic congruence (5) has no solution or three solutions. Case. Let p 3(mod ). Since 1 / Q p,k F p\q p and k r (mod p), wehave k Q p. Therefore D k(k +1) Q p, that is, ( D p )=1. So also in this case, the cubic congruence (5) has no solutions or three solutions. Hence we have the following corollary: Corollary.: For p>3 is a prime, the cubic congruence x 3 + x + kx r 0(mod p) has no solution or three solutions. Now we will show that this cubic congruence has three solutions. Lemma.1: Let k+r = p. Then the solutions of the cubic congruence are r, r and. x 3 + x + kx r 0(mod p) Proof: If we take k = p r, then by (5) we have x 3 + x r x r = (x + 1)(x + r)(x r) 0(mod p). This shows that only solutions of this congruence are r, r and. Consequently, the cubic congruence x 3 + x + kx r 0(mod p) has three solutions for k + r = p. But the points from this cubic congruence can not be the expected ones, that is, the points can not be on both elliptic curve and the circle family. Solutions of this congruence also verify the circle equation x +y = r. In this way, for each x, r x must be a square in. In other words, only the solutions which make r x a square will give us what we require. For x = ±r, r x equals to zero, so it is clear that both (r, 0) and ( r, 0) points must be on the two curve families. If r () is not a square in, then x = can not be a point on both curve families. Now, we will determine that when this point is a common point of two curve families. To do this we have to consider two cases: Case 1. Let p 1(mod ). If we write x = in y = x 3 + kx, then we have Since y =() 3 + k() (k + 1)(mod p). (k +1) Q p (k +1) Q p this implies that, (, ± r 1) are desired points if and only if k, k +1 Q p. We know that k Q p. Hence i) If k +1 / Q p, then common points of elliptic curve and circle family are (r, 0), ( r, 0). ii) If k +1 Q p, then common points of elliptic curve and circle family are (r, 0),( r, 0), (, ± r 1). Case. Let p 3(mod ). In this case we know that k F p\q p. Therefore (k +1) Q p (k +1) F p\q p. International Scholarly and Scientific Research & Innovation (7) 008 78 scholar.waset.org/1307-689/178

Vol:, No:7, 008 International Science Index, Mathematical and Computational Sciences Vol:, No:7, 008 waset.org/publication/178 This implies that, (, ± r 1) are desired points if and only if k, k +1 F p\q p. We know that k F p\q p. Hence i) If k +1 / F p\q p, then common points of elliptic curve and circle family are (r, 0) and ( r, 0). ii) If k +1 F p\q p, then common points of elliptic curve and circle family are (r, 0), ( r, 0), (, ± r 1). So we proved the following theorem. Theorem.3: Let p>3 be a prime and let k + r = p. Then for elliptic curve family and circle family E k : y = x 3 + kx C r : x + y = r with each x is a solution of the equation (5), and ( ) r if x =0 E k C r = ( ) r if x =1, where E k C r denotes the number of the common ( ) r By generalizing the Legendre symbol to any field, x ( r x ) =1if t = r x has a solution t F p; means that, ( ) r x = 1 if t = r x has no solution t F p and ( r x =0if r = x. Thus, common points of elliptic curve and circle family are (r, 0), ( r, 0) and in addition to this points, we have (, ± ( ) r 1) if r () =1. ) In, elliptic curve family y = x 3 + kx and circle family x + y = r may not have common Let s see the following example. Example.1: 1) Let E be the elliptic curve y = x 3 +x and C 1 be the circle x + y =1over F 7. Then the cubic congruence x 3 + x +x 1 0(mod 7) has no solution. Therefore E and C 1 have no common points in F 7. ) Let E be the elliptic curve y = x 3 +x and C be the circle x + y =over F 7. Then the cubic congruence x 3 + x +x 0(mod 7) has only one solution x 5(mod 7). Then from the circle equation we yield, +y (mod 7) or y 5(mod 7), but 5 / Q 7. So there is no y value, satisfying this equation. Therefore E and C have no common points in F 7. Now we will determine how many circles and elliptic curves have intersection for a prime p. We have to consider following two cases. Case 1. Let p 1(mod ). Then k Q p and k + r = p. So elliptic curve and circle family have intersection. Thus, the number of intersection of these two curve families is Q p, namely there are circles and elliptic curves families which have intersection. Case. Let p 3(mod ). Then k F p\q p. So there are = circles and elliptic curves families which have intersection, that is, in this case the number of intersection of these two curve families is, too. Corollary.: For a prime p>3, the number of intersection of the elliptic curve family y = x 3 + kx and the circle family x + y = r in is. Example.: Let E k : y = x 3 + kx and C r : x + y = r. 1) If p =13, then we have the following table: k r points 1 1 (5, 0), (8, 0) 3 10 (6, 0), (7, 0), (1, 3), (1, 10) 9 (3, 0), (10, 0) 9 (, 0), (11, 0), (1, ), (1, 9) 10 3 (, 0), (9, 0) 1 1 (1, 0), (1, 0) ) If p =19, then we have the following table: k r points 17 (6, 0), (13, 0), (18, ), (18, 15) 3 16 (, 0), (15, 0) 8 11 (7, 0), (1, 0) 10 9 (3, 0), (16, 0) 1 7 (11, 0), (8, 0), (18, 5), (18, 1) 13 6 (5, 0), (1, 0), (18, 9), (18, 10) 1 5 (9, 0), (10, 0), (18, ), (18, 17) 15 (, 0), (17, 0) 18 1 (1, 0), (18, 0) International Scholarly and Scientific Research & Innovation (7) 008 79 scholar.waset.org/1307-689/178

Vol:, No:7, 008 International Science Index, Mathematical and Computational Sciences Vol:, No:7, 008 waset.org/publication/178 Now we will determine the number of intersection of elliptic curve and circle families which has the points (r, 0), ( r, 0) and (r, 0), ( r, 0), (, ± r 1). We have to consider two cases as we did before. But we need to know the following theorem. In [1] it is given that, Theorem.5: Let N(p) denote the number of pairs of consecutive quadratic residues modulo p in. Then (p ( 1) ) N(p) =. Let N(p) denote the number of pairs of consecutive integers in, where the first is a quadratic nonresidue and the second is a quadratic nonresidue modulo p and N(p) (p +( 1) ) =. Then we have two cases: Case 1. Let p 1(mod ). Then (, ± r 1) are desired points if and only if k, k +1 Q p by the proof of Theorem.3. Hence, by Theorem.5, the number of cases where the intersection of elliptic curve and circle has four points which are (, ± r 1) and (±r, 0) is (p ( 1) ) N(p) = N(p) = p ( 1) = p ++( 1) Example.3: Let p =13. Then the number of cases where the intersection of elliptic curve and circle has four points which are (, ± r 1) and (±r, 0) is 13 1 (13 ( 1) ) N(13) = = 13 1 N(13) = 6 =. These curves can be seen in Example.. Case. Let p 3(mod ). Then (, ± r 1) are desired points if and only if k, k +1 F p\q p by the proof of Theorem.3. Hence by Theorem.5, the number of cases where the intersection of elliptic curve and circle has four points which are (, ± r 1) and (±r, 0) is N(p) (p +( 1) ) = N(p) = = p ( 1) (p +( 1) ).. Example.: Let p =19. Then the number of cases where the intersection of elliptic curve and circle has four points which are (, ± r 1) and (±r, 0) is 19 1 N(19) (19 +( 1) ) = = 19 1 N(19) =9 =5. These curves can be seen in Example.. Therefore we have the following result. Theorem.6: The number of cases where the intersection of elliptic curve and circle has four points which are (p 1, ± r 1) and (±r, 0) is N(p) = N(p) = (p ( 1) ) if p 1(mod ) (p +( 1) ) if p 3(mod ) N(p) = p++( 1) if p 1(mod ) N(p) = p ( 1) if p 3(mod ). We can also determine how many points are there in the intersection of the elliptic curve y = x 3 + kx and circle x + y = r. We know that there are the points (±r, 0), and we know that there are elliptic curve families. So the number of these points is ( ) =. In addition to these points, there are the points (, ± r 1). Soifp 1(mod ), then the number of these points is N(p) and if p 3(mod ) then the number of these points is N(p). Therefore we have the following corollary. Corollary.7: The number of the common points of the elliptic curve family y = x 3 + kx together with the circle family x + y = r is +N(p) = +N(p) = 3p 6 ( 1) if p 1(mod ) 3p +( 1) if p 3(mod ). International Scholarly and Scientific Research & Innovation (7) 008 80 scholar.waset.org/1307-689/178

Vol:, No:7, 008 International Science Index, Mathematical and Computational Sciences Vol:, No:7, 008 waset.org/publication/178 Example.5: 1) Let p = 13. Then the number of the common points of the elliptic curve family together with the circle family is 13 1+N(13) = 16. ) Let p =19. Then the number of the common points of the elliptic curve family together with the circle family is 19 1+N(19) =6. For any numbers k and r if ( D p ) = 1, then the cubic congruence (5) has either no solution or three solutions. If the cubic congruence (5) has no solution, then elliptic curve family and circle family have any common Let the cubic congruence (5) has three solutions. In this case, if for each three solution x, and r x is a square in, then elliptic curve and circle have six common If for two solutions r x is a square in, then they have four common points and if for one solution r x is a square ( in, ) then they have two common Furthermore, if r x =0namely, r x =0, then there are two or four common points, as we seen before in our case. Therefore, in the general case they may have zero, two, four or six common Example.6: 1) Let E 1 : y = x 3 +x and C : x +y = over F 13. Then the cubic congruence x 3 + x + x 0(mod 13) has no solution. Therefore E 1 and C have no common ) Let E 6 : y = x 3 +6x and C 9 : x + y =9over F 19. Then the cubic congruence x 3 + x +6x 9 0(mod 19) has three solutions which are x 1 =,x =5and x 3 =9.It can be seen that only one solution makes r x a square in F 19. In fact, for x 1 =we get that 16 + y 9(mod 19) or y 1(mod 19), but1 / Q 19. So there is no y value satisfying this equation and we have no For x =5 we get that 6+y 9(mod 19) or y 3(mod 19), but 3 / Q 19. So there is no y value satisfying this equation and we have no points and for x 3 =9from the circle equation we get that 5+y 9(mod 19) or y (mod 19). Sowe have the points (9, ), (9, 17). Therefore elliptic curve E 6 and circle C 9 have two common 3) Let E 1 : y = x 3 + x and C 1 : x + y =1over F 11. Then the cubic congruence x 3 + x + x 1 0(mod 11) has three solutions which are x 1 =5,x,3 =8. It also can be easily seen that these solutions make r x a square in F 11. In fact, for x 1 =5from the circle equation we get that 3+y 1(mod 11) or y 9(mod 11). So we have the points (5, 5), (5, 1) and for x,3 =8we get that 9+y 1(mod 11) or y 3(mod 11). So we have the points (8, 5), (8, 6). Therefore elliptic curve E 1 and circle C 1 have four common ) Let E 1 : y = x 3 +1x and C 16 : x + y =16over F 17. Then the cubic congruence x 3 + x +1x 16 0(mod 17) has three solutions which are x 1 =1,x =5and x 3 =10.It can be easily seen that these solutions make r x a square in F 17. In fact, for x 1 =1from the circle equation we get that 1+y 16(mod 17) or y 15(mod 17). Sowehave the points (1, 7), (1, 10) and for x =5we get that 8+y 16(mod 17) or y 8(mod 17). So we have the points (5, 5), (5, 1) and for x 3 =10we get that 15 + y 16(mod 17) or y 1(mod 17). So we have the points (10, 1) and (10, 16). Therefore elliptic curve E 1 and circle C 16 have six common In second case, for any numbers k and r if ( D p )= 1, then the cubic congruence (5) has only one solution x and if for this solution, r x is a square in, then the elliptic curve and circle have two common points over. Therefore in this case, they may have zero or two common Let s see these situations in the following example. Example.7: 1) If E 1 : y = x 3 + x and C 1 : x + y =1 over F 7. Then the cubic congruence x 3 + x + x 1 0(mod 7) has only one solution which is x = 5. We can easily see that this solution makes r x a square in F 7. In fact, for x =5from the circle equation we get that +y 1(mod 7) or y (mod 7). So we have the points (5, ) and (5, 5). Therefore E 1 and C 1 have two common ) If E 3 : y = x 3 +3x and C 1 : x + y =1over F 7. Then the cubic congruence x 3 + x +3x 1 0(mod 7) has only one solution which is x =. We can easily see that this solution does not make r x a square in F 7. In fact, for x = from the circle equation we get that +y 1(mod 7) or y 6(mod 7), but6 / Q 7. So there is no y value satisfying this equation and so we have no Therefore elliptic curve E 3 and circle C 1 have no common REFERENCES [1] G.E. Andrews. Number Theory. Dover Pub., 1971. [] L.E. Dickson. Criteria for irreducibility of functions in a finite field. Bull, Amer. Math. Soc. 13(1906), 1 8. [3] B. Gezer, H. Özden, A. Tekcan and O. Bizim. The Number of Rational Points on Elliptic Curves y = x 3 +b over Finite Fields. IInternational Journal of Mathematics Sciences 1(3)(007), 178 18. [] L.J. Mordell. On the Rational Solutions of the Indeterminate Equations of the Third and Fourth Degrees. Proc. Cambridge Philos. Soc. 1(19), 179 19. International Scholarly and Scientific Research & Innovation (7) 008 81 scholar.waset.org/1307-689/178

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