Antenna and communication device

What is claimed is: 1 . An antenna, comprising: a dielectric substrate; a combined line disposed on the dielectric substrate, wherein the combined line has a first end and a second end; a folded dipole disposed on the dielectric substrate, wherein the folded dipole is located at the first end of the combined line and is connected to the combined line; and N symmetrical dipoles disposed on the dielectric substrate, wherein the N symmetrical dipoles are connected to the combined line, and N is an integer greater than or equal to 1, and when N is greater than 1, the N symmetrical dipoles are sequentially arranged from the first end to the second end of the combined line, wherein the combined line comprises a first microstrip and a second microstrip, the first microstrip and the second microstrip are provided in parallel, and a gap exists between the first microstrip and the second microstrip, wherein the folded dipole comprises a first connecting arm and a second connecting arm, the first connecting arm is connected to an end of the first microstrip, and the second connecting arm is connected to an end of the second microstrip, wherein the first connecting arm has a first extension section extending in a direction away from the second connecting arm, and the second connecting arm has a second extension section extending in a direction away from the first connecting arm. 2 . The antenna according to claim 1 , wherein a distance between the folded dipole and the symmetrical dipole at a tail part is L; the symmetrical dipole at the tail part is a symmetrical dipole located at a second end of the combined line; and L ranges from a quarter of an operating wavelength of the antenna to an entire operating wavelength. 3 . The antenna according to claim 2 , wherein L is equal to half of the operating wavelength of the antenna. 4 . The antenna according to claim 3 , wherein the combined line comprises a first microstrip and a second microstrip; and the first microstrip and the second microstrip are provided in parallel, and a gap exists between the first microstrip and the second microstrip. 5 . The antenna according to claim 2 , wherein the combined line comprises a first microstrip and a second microstrip; and the first microstrip and the second microstrip are provided in parallel, and a gap exists between the first microstrip and the second microstrip. 6 . The antenna according to claim 1 , wherein the symmetrical dipole comprises a first vibration arm and a second vibration arm, and the first vibration arm and the second vibration arm are symmetrically configured relative to the combined line; and the first vibration arm is located on a side of the first microstrip and an end that is of the first vibration arm and that is close to the first microstrip is connected to the first microstrip; and the second vibration arm is located on a side of the second microstrip and an end that is of the second vibration arm and that is close to the second microstrip is connected to the second microstrip. 7 . The antenna according to claim 6 , wherein in the symmetrical dipole at the tail part, the first vibration arm has a first feed end, and the first feed end is located at an end that is of the first vibration arm and that faces the second vibration arm; the second vibration arm has a second feed end, and the second feed end is located at an end that is of the second vibration arm and that faces the first vibration arm; and the symmetrical dipole at the tail part is a symmetrical dipole located at the second end of the combined line. 8 . The antenna according to claim 6 , wherein the folded dipole comprises a first connecting arm and a second connecting arm, the first connecting arm is connected to an end of the first microstrip, and the second connecting arm is connected to an end of the second microstrip. 9 . The antenna according to claim 7 , wherein the antenna further comprises a balun structure; and the balun structure is disposed on a side that is of the symmetrical dipole at the tail part and that is away from the folded dipole, and is connected to the symmetrical dipole at the tail part. 10 . The antenna according to claim 7 , wherein the folded dipole comprises a first connecting arm and a second connecting arm, the first connecting arm is connected to an end of the first microstrip, and the second connecting arm is connected to an end of the second microstrip. 11 . The antenna according to claim 9 , wherein the balun structure is a bent U-shaped structure; and one end of the balun structure is connected to the first vibration arm, and the other end is connected to the second vibration arm. 12 . The antenna according to claim 9 , wherein the folded dipole comprises a first connecting arm and a second connecting arm, the first connecting arm is connected to an end of the first microstrip, and the second connecting arm is connected to an end of the second microstrip. 13 . The antenna according to claim 1 , wherein the symmetrical dipole at the tail part comprises a first vibration arm and a second vibration arm, and the first vibration arm and the second vibration arm are symmetrically configured relative to the combined line; an end close to the first vibration arm and an end close to the second vibration arm are connected to each other, and a slot exists between the first vibration arm and the second vibration arm; an end that is of the first vibration arm and that is close to the first microstrip is connected to the first microstrip, and an end of the second microstrip is located in the slot; and the symmetrical dipole at the tail part is a symmetrical dipole located at a second end of the combined line, the first vibration arm or the second vibration arm has a first feed end, and the second microstrip has a second feed end. 14 . The antenna according to claim 1 , wherein the N symmetrical dipoles satisfy: L n L n + 1 = < 1 wherein n is a sequence number of the symmetrical dipole and increases sequentially from the first end to the second end of the combined line; L n is a length of an n th symmetrical dipole; L n+1 is a length of an (n+1) th symmetrical dipole; and τ is a combination factor of the antenna. 15 . The antenna according to claim 1 , wherein the N symmetrical dipoles satisfy: R n R n + 1 = o ^ < 1 wherein n is the sequence number of the symmetrical dipole and increases sequentially from the first end to the second end of the combined line; R n is a distance from the n th symmetrical dipole to a virtual vertex of the antenna; R n+1 is a distance from the (n+1) th symmetrical dipole to the virtual vertex of