A tread pattern of a tire includes: a circumferential main groove extending in a tire circumferential direction; a plurality of sipes extending in a tire width direction within a region of a land portion in contact in the tire width direction with the circumferential main groove; and a chamfered surface having a tread surface of the land portion inclined toward the circumferential main groove in an end portion in the tire width direction on a circumferential main groove side of the land portion, the chamfered surface being provided in a plurality in the tire circumferential direction, and the sipes opening to the plurality of the chamfered surfaces without reaching a groove wall of the circumferential main groove. The length of the chamfered surface in the tire circumferential direction is greater than the length thereof in the tire width direction.

A tire tread includes a pair of first circumferential main grooves in a first half-tread region on one side in a tire width direction, a pair of second circumferential main grooves in a second half-tread region, first sipes provided in a first region between the first circumferential main grooves, a circumferential narrow groove having a groove width smaller than a groove width of the first circumferential main groove and extending in the tire circumferential direction within the first region, and sipes in a second region between the second circumferential main grooves, extending in the tire width direction, and closing within the second region. The number of intervals of the second sipes mutually adjacent is larger than the number of intervals of the first sipes mutually adjacent.

A tyre comprises a tread portion comprising a shoulder main groove and a shoulder land region. The shoulder land region includes an outer region, a middle region, and an inner region. The shoulder land region is provided with a plurality of shoulder sipes having components in a tyre axial direction. A sipe ratio of the middle region is smaller than the sipe ratio of the outer region and the sipe ratio of the inner region.

A tire has a tread portion that can include a first tread ground contact end on one side in a tire axial direction, a first shoulder circumferential groove closest to the first tread ground contact end, and a first shoulder land portion demarcated to be disposed outwardly of the first shoulder circumferential groove in the tire axial direction. A plurality of first shoulder grove portions extending from the first shoulder circumferential groove to the first tread ground contact end e1 can be in the first shoulder land portion. A pair of first shoulder groove portions adjacent to each other in a tire circumferential direction can have different angles relative to the tire axial direction. The plurality of first shoulder groove portions can include a plurality of kinds of first shoulder groove portions having different first pitch lengths at a connecting portion to the first shoulder circumferential groove. A maximum value of the first pitch length can be 1.2 to 1.5 times an average of the first pitch lengths.

A tire has a tread comprising at least two tread pattern elements (MA, MB) distributed periodically in the circumferential direction at pitches (PA, PB). Each tread pattern element is formed of three portions (Z1, Z2, Z3), each defining a volumetric element of which the leading edge corner is the one common to the tread surface and is the first to enter the contact patch in which the tire is in contact with the ground. With each leading edge corner being chamfered, in the portions Z1 and/or Z2, and/or Z3, the widths of the chamfers of the leading edge corners (LC.sub.i.sup.A, LC.sub.i.sup.B, i ranging from 1 to 3) satisfy the following inequalities: a) for the portion Z1:

[00001]$\left[\left[\right]\right]0.8*\frac{PA}{PB}\le \frac{L{C}_1^A}{L{C}_1^B}\le \frac{PA}{PB}*1.2;$

b) for the portion Z2:

[00002]$\left[\left[\right]\right]0.8*\frac{PA}{PB}\le \frac{L{C}_2^A}{L{C}_2^B}\le \frac{PA}{PB}*1.2;$

and c) for the portion Z3:

[00003]