RU2003100396A - METHOD FOR DETERMINING MOTION VECTORS IN DIRECT PREDICTION MODE FOR B-FRAME - Google Patents

Claims (37)

1. The method of determining motion vectors in direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in direct prediction mode, which means that any of the displacement block motion vectors in the reference frame of list 1 for the direct prediction mode as a motion vector for obtaining said motion vectors in the direct prediction mode regardless of the modes (list mode 0 and / or list mode 1) mentioned motion vectors of said displaced block, taking a reference picture pointed by the selected motion vector as a list 0 reference picture for direct mode to obtain motion vectors of the B picture in direct mode. 2. A method for determining motion vectors in the direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in a direct prediction mode, namely, if the offset block in the reference frame of list 1 for the direct prediction mode has only one motion vector of list 1, then use the mentioned motion vector of list 1 as a motion vector to obtain the mentioned motion vectors in direct prediction mode, when imayut reference picture pointed by the list 1 motion vector as a list 0 reference picture for direct mode to obtain motion vectors of the B picture in direct mode. 3. A method for determining motion vectors in the direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in a direct prediction mode, namely, if the offset block in the reference frame of list 1 for the direct prediction mode has only one motion vector of list 1, then the said offset block is assumed to be a block with zero movement, a decoded frame located in time immediately before the B-frame is received, as the reference frame of list 0 for the direct prediction mode, and the motion vectors of the B-frame in the direct prediction mode are obtained. 4. A method for determining motion vectors in direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in direct prediction mode, which is that if the offset block in the reference frame of list 1 for the direct prediction mode has only one motion vector of list 1, then the mentioned motion vector of list 1 of the shifted block is used as the motion vector to obtain the mentioned motion vectors in direct mode redskazaniya, accept the decoded frame, located in time just before said B picture as a list 0 reference picture for direct mode prediction and determine the motion vectors of the B picture in direct mode. 5. A method for determining motion vectors in the direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in a direct prediction mode, namely, if the offset block in the reference frame of list 1 for the direct prediction mode has two motion vectors, then select any of the two mentioned motion vectors (list motion vector 0 or list 1 motion vector) and obtain the motion vectors of the said B-frame in direct mode a prediction of the selected vector. 6. The method according to claim 5, characterized in that the said motion vector of list 0 is unconditionally selected as the motion vector to obtain said motion vectors in direct prediction mode, regardless of the time interval, a reference frame is received, which is indicated by the motion vector of list 0, as the reference frame of list 0 for the direct prediction mode, and the motion vectors of the B-frame in the direct prediction mode are obtained. 7. The method according to claim 5, characterized in that one of said motion vectors of list 0 and list 1 is selected, which indicates a frame closest in time to said reference frame of list 1 for direct prediction mode, as a motion vector for obtaining said vectors motion in direct prediction mode, select said list motion vector 0 as the motion vector to obtain said motion vectors in direct prediction if both of these motion vectors point to the same reference nth frame, the reference frame indicated by the selected motion vector is received as the reference frame of list 0 for the direct prediction mode, and the motion vectors of the B-frame in the direct prediction mode are determined. 8. A method for determining motion vectors in direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in direct prediction mode, which sets the last decoded frame as a reference frame of the list 1 for the direct prediction mode, the motion vector of the biased block is scaled in said reference frame of list 1 for the direct prediction mode to obtain a motion vector MV _F and a list 0 motion vector MV _B list 1, and determining the motion vectors of the B picture in direct mode. 9. A method for determining motion vectors in the direct prediction mode for a B-frame (bidirectional prediction frame) in a moving image coding system for obtaining motion vectors of a B-frame in a direct prediction mode, namely, if the reference frame of list 1 for the direct mode prediction is preceded in time by said B-frame, then the motion vector of the shifted block is scaled in said reference frame of list 1 for the direct prediction mode to obtain the motion vector MV _F lane The target is 0 and the motion vector MV _{B is} List 1, and the motion vectors of said B-frame are determined in the direct prediction mode. 10. The method according to claim 9, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in a single-frame mode and the reference frame of List 0 for the direct prediction mode is preceded in time by said reference frame of List 1, then the motion vectors MV _F and MV _{B of the} said B-frame in the direct prediction mode are calculated as follows: MV _F = TD _B MV / TD _D , MV _B = (TD _B -TD _D ) MV / TD _D , or Z = TV _B 256 / TD _D , MV _F = (Z MV + 128) >> 8, W = Z-256, MV _B = (W · MV + 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of the offset block in the reference frame of list 1 for the direct prediction mode. 11. The method according to claim 9, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in a single-frame mode and the reference frame of List 0 for the direct prediction mode follows in time the reference frame of List 1 then the motion vectors MV _F and MV _{B of} said B-frame in the direct prediction mode are calculated as follows: MV _F = -TD _B MV / TD _D , MV _B = - (TD _B + TD _D ) MV / TD _D , or Z = -TV _B · 256 / TD _D , MV _F = (Z · MV + 128) >> 8, W = Z-256, MV _B = (W · MV + 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of the shifted block in the reference frame of List 1 for the direct prediction mode. 12. The method according to claim 9, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in the field mode, and the reference frame of List 0 for the direct prediction mode is preceded in time by the reference frame of List 1, then the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = TD _{B, i} MV _i / TD _{D, i} , MV _{B, i} = (TD _{B, i-} TD _{D, i} ) MV _i / TD _{D, i} , or Z = TV _{B, i} · 256 / TD _{D, I} , MV _{F, i} = (Z · MV _i +128) >> 8, W = Z-256, MV _{B, i} = (WV MV _i +128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D , _i is the time interval between the reference field of list 1 and the reference field of list 0; MV _i is the motion vector of the displaced block in the reference field of list 1 for the direct prediction mode. 13. The method according to claim 9, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in the field mode, and the reference frame of List 0 for the direct prediction mode follows in time the reference frame of List 1 , then the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = -TD _{B, i} MV _i / TD _{D, i} , MV _{B, i} = - (TD _{B, i} + TD _{D, i} ) MV _i / TD _{D, i} , or Z = -TD _{B, i} · 256 / TD _{D, I} , MV _{F, i} = (Z · MV _i +128) >> 8, W = Z-256, MV _{B, i} = (WV MV _i +128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D , _i is the time interval between the reference field of list 1 and the reference field of list 0; MV ₁ is the motion vector of the displaced block in the reference field of list 1 for the direct prediction mode. 14. The method according to claim 9, characterized in that if the macroblock of said B-frame is used in field mode, the offset macroblock of said reference frame of list 1 is used in frame mode, and the reference frame of list 0 for direct prediction mode is preceded by a reference frame in time list 1, then the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = TD _{B, i} MV / TD _D , MV _{B, i} = (TD _{B, i-} TD _D ) MV / TD _D , or Z = TV _{B, i} · 256 / TD _D , MV _{F, i} = (Z · MV + 128) >> 8, W = Z-256, MV _{B, i} = (W · MV + 128) >> 8, where TD _b , _i is the time interval between the current B-field and the reference field of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of the offset block in the reference frame of list 1 for the direct prediction mode. 15. The method according to claim 9, characterized in that if the macroblock of said B-frame is used in field mode, the offset macroblock of said reference frame of list 1 is used in single-frame mode, and the reference frame of list 0 for direct prediction mode follows in time after said reference frame of list 1, the motion vectors MV _Fi and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = -TD _{B, i} MV / TD _D , MV _{B, i} = - (TD _{B, i} + TD _D ) MV / TD _D , or Z = -TD _{B, i} · 256 / TD _D , MV _{F, i} = (Z · MV + 128) >> 8, W = Z-256, MV _{B, i} = (W · MV + 128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of the offset block in the reference frame of list 1 for the direct prediction mode. 16. The method according to claim 9, characterized in that if the macroblock of said B-frame is used in single-frame mode, the offset macroblock of said reference frame of list 1 is used in field mode, and the reference frame of list 0 for direct prediction mode of said B-frame is preceded in time of the reference frame of List 1, then the motion vectors MV _F and MV _{B of the B} -frame are obtained from the following equations in which information about the movement of the displaced block in field 1 of the reference frame of List 1 is used to calculate the motion vectors in the direct pre legends: MV _F = TD _B MV ₁ / TD _{D, 1} , MV _B = (TD _B -TD _{D, 1} ) MV ₁ / TD _{D, 1} , or Z = _B · TV 256 / TD _{D, 1,} MV _F = (Z · MV ₁ + 128) >> 8, W = Z-256, MV _B = (W · MV ₁ +128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D , ₁ - time interval between field 1 of the reference frame of list 1 and the reference field of list 0; MV ₁ is the motion vector of the offset block in field 1 of the reference frame of list 1 for the direct prediction mode. 17. The method according to claim 9, characterized in that if the macroblock of said B-frame is used in single-frame mode, the offset macroblock of said reference frame of said list 1 is used in field mode, and the reference frame of list 0 for direct prediction mode of said B-frame follows the reference frame of list 1 in time, the motion vectors MV _F and MV _{B of the B} -frame in direct prediction mode are obtained from the following equations in which information about the movement of the displaced block in field 1 of the reference frame of list 1 is used to calculate the motion vectors Direct prediction mode: MV _F = -TD _B MV ₁ / TD _{D, 1} , MV _B = - (TD _B + TD _{D, 1} ) MV ₁ / TD _{D, 1} , or Z = -TV _B · 256 / TD _{D, 1} , MV _F = (Z · MV ₁ +128) >> 8, W = Z-256, MV _B = (W · MV ₁ +128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D , ₁ - time interval between field 1 of the reference frame of list 1 and the reference field of list 0; MV ₁ is the motion vector of the offset block in field 1 of the reference frame of list 1 for the direct prediction mode. 18. The method of determining the motion vectors of the B-frame (bidirectional prediction frame) in the direct prediction mode in the coding system of the moving image to obtain the motion vectors of the B-frame in the direct prediction mode, namely, if the reference frame of the list 0 and the reference frame of the list 1 for the direct prediction mode is followed by a B-frame in time, then the motion vector of the biased block is scaled in the reference frame of list 1 for the direct prediction mode to obtain a motion vector MV _F and a list 0 motion vector MV _B list 1, and determining the motion vectors of the B picture in direct mode. 19. The method according to p. 18, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of list 1 are used in a single-frame mode and said reference frame of list 0 for the direct prediction mode follows the reference frame of list 1 in time, then the motion vectors MV _F and MV _{B of the B} -frame in direct prediction mode are calculated as follows: MV _F = TD _B MV / TD _D , MV _B = (TD _B -TD _D ) MV / TD _D , or Z = TV _B 256 / TD _D , MV _F = (Z MV + 128) >> 8, W = Z-256, MV _B = (W · MV + 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of said offset block in said reference frame of List 1 for the direct prediction mode. 20. The method according to p. 18, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of list 1 are used in a single-frame mode, and said reference frame of list 0 for the direct prediction mode is preceded in time by said reference frame of list 1 then the motion vectors MV _F and MV _{B of the} specified B-frame in the direct prediction mode are calculated as follows: MV _F = -TD _B MV / TD _D , MV _B = - (TD _B + TD _D ) MV / TD _D , or Z = -TD _B · 256 _{/ TD D, MV F = (} Z · MV + 128) >> 8, W = Z-256, MV _B = (W · MV + 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of said offset block in said reference frame of List 1 for the direct prediction mode. 21. The method according to p. 18, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in the field mode, and said reference frame of List 0 for the direct prediction mode follows in time the reference frame of the list 1, the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = TD _{B, i} MV _i / TD _{D, i} , MV _{B, i} = (TD _{B, i-} TD _{D, i} ) MV _i / TD _{D, i} , or Z = TV _{B, i} · 256 / TD _{D, I} , MV _{F, i} = (Z · MV _i +128) >> 8, W = Z-256, MV _{B, i} = (WV MV _i +128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D , _i is the time interval between the reference field of list 1 and the reference field of list 0; MV _i is the motion vector of the displaced block in the reference field of list 1 for the direct prediction mode. 22. The method according to p. 18, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in the field mode, and said reference frame of List 0 for the direct prediction mode is preceded in time by the reference frame of List 1 , the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = -TD _{B, i} MV _i / TD _{D, i} , MV _{B, i} = - (TD _{B, i} + TD _{D, i} ) MV _i / TD _{D, i} , or Z = -TV _{B, i} · 256 / TD _{D, I} , MV _{F, i} = (Z · MV _i +128) >> 8, W = Z-256, MV _{B, i} = (WV MV _i +128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D , _i is the time interval between the reference field of list 1 and the reference field of list 0; MV _i is the motion vector of the displaced block in the reference field of list 1 for the direct prediction mode. 23. The method according to p. 18, characterized in that if the macroblock of said B-frame is used in field mode, the offset macroblock of said reference frame of list 1 is used in single-frame mode, and said reference frame of list 0 for direct prediction mode follows in time after the reference frame of list 1, the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = TD _{B, i} MV / TD _D , MV _{B, i} = (TD _{B, i-} TD _D ) MV / TD _D , or Z = TD _{B, i} · 256 / TD _D , MV _{F, i} = (Z · MV + 128) >> 8, W = Z-256, MV _{B, i} = (W · MV + 128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of the offset block in the reference frame of list 1 for the direct prediction mode. 24. The method according to p. 18, characterized in that if the macroblock of said B-frame is used in field mode, the offset macroblock of said reference frame of list 1 is used in single-frame mode, and said reference frame of list 0 for direct prediction mode is preceded by time mentioned the reference frame of list 1, then the motion vectors MV _F , _i and MV _B , _i in the direct prediction mode for each i-field of the B-frame are calculated as follows: MV _{F, i} = -TD _{B, i} MV / TD _D , MV _{B, i} = - (TD _{B, i} + TD _D ) MV / TD _D , or Z = -TV _{B, i} · 256 / TD _D , MV _{F, i} = (Z · MV + 128) >> 8, W = Z-256, MV _{B, i} = (W · MV + 128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of the list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0; MV is the motion vector of the offset block in the reference frame of list 1 for the direct prediction mode. 25. The method according to p. 18, characterized in that if the macroblock of said B-frame is used in single-frame mode, the offset macroblock of said reference frame of list 1 is used in field mode, and said reference frame of list 0 for direct prediction mode follows in time the reference frame of the list 1, the motion vectors MV _F and MV _{B of the B} -frame are calculated according to the following equations, in which the information about the motion of the offset block in the field 0 of the reference frame of the list 1 is used to calculate the motion vectors in the direct prediction mode: MV _F = TD _B MV ₀ / TD _{D, 0} , MV _B = (TD _B -TD _{D, 0} ) MV ₀ / TD _{D, 0} , or Z = TD _B · 256 / TD _{D, 0,} MV _F = (Z · MV ₀ + 128) >> 8, W = Z-256, MV _B = (WV MV _{0 +} 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D , ₀ - time interval between field 0 of the reference frame of list 1 and the reference field of list 0; MV ₀ is the motion vector of the displaced block in field 0 of the reference frame of list 1 for the direct prediction mode. 26. The method according to p. 18, characterized in that if the macroblock of said B-frame is used in single-frame mode, the offset macroblock of said reference frame of list 1 is used in field mode, and said reference frame of list 0 for direct prediction mode is preceded by time mentioned list 1 reference picture, motion vectors MV _F and MV _B of a B picture in direct mode is calculated by the following equations, in which the motion information located block in the field 0 of the list 1 reference frame is used for calculation of the vectors d izheniya direct mode: MV _F = -TD _B MV ₀ / TD _{D, 0} , MV _B = - (TD _B + TD _{D, 0} ) xMV ₀ / TD _{D, 0} , or Z = -TV _B · 256 / TD _{D, 0} , MV _F = (Z · MV ₀ +128) >> 8, W = Z-256, MV _B = (WV MV _{0 +} 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of the list 0; TD _D , ₀ - time interval between field 0 of the reference frame of list 1 and the reference field of list 0; MV ₀ is the motion vector of the displaced block in field 0 of the reference frame of list 1 for the direct prediction mode. 27. The method of determining the motion vectors of the B-frame (bidirectional prediction frame) in the direct prediction mode in the moving picture coding system to obtain the motion vectors of the B-frame in the direct prediction mode, which consists in assigning a sign to the size of the inter-frame time interval, scaling the vector movement of the offset block in the reference frame of list 1 for the direct prediction mode, regardless of the positions of the reference frames of lists 0 and 1 for the direct prediction mode, to obtain the motion vector MV _{F of} list 0 and the motion vector MV _{B of} list 1, and determine the motion vectors of the specified B-frame in direct prediction mode. 28. The method according to claim 27, characterized in that if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in single-frame mode, the motion vectors MV _F and MV _{B of the B} -frame in direct prediction mode are calculated as follows: MV _F = TD _B MV / TD _D , MV _B = (TD _B -TD _D ) MV / TD _D , or Z = TD _B 256 / TD _D , MV _F = (Z MV + 128) >> 8, W = Z-256, MV _B = (W · MV + 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of list 0, which is assigned a positive sign (+) if this interval is measured from the B-frame, and a negative sign (-) if this interval is measured from the reference frame of list 0 ; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0, which is assigned a positive sign (+) if this interval is measured from the reference frame of list 1, and a negative sign (-) if this interval is measured from the reference frame of list 0 ; MV is the motion vector of said offset block in the reference frame of list 1 for the direct prediction mode. 29. The method according to claim 27, wherein if the macroblock of said B-frame and the offset macroblock of said reference frame of List 1 are used in field mode, the motion vectors MV _F , _i and MV _B , _i in direct prediction mode for each i B-frame fields are calculated as follows: MV _{F, i} = TD _{B, i} MV _i / TD _{D, i} , MV _{B, i} = (TD _{B, i-} TD _{D, i} ) MV _i / TD _{D, i} , or Z = TD _{B, i} · 256 / TD _{D, I} , MV _{F, i} = (Z · MV _i +128) >> 8, W = Z-256, MV _{B, i} = (WV MV _i +128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of list 0, which is assigned a positive sign (+) if this interval is measured from the B-field, or a negative sign (-) if this interval is measured from the reference field list 0; TD _D , _i is the time interval between the reference field of list 1 and the reference field of list 0, which is assigned a positive sign (+) if this interval is measured from the reference field of list 1, or a negative sign (-) if this interval is measured from the reference field list 0; MV _i is the motion vector of the displaced block in the reference field of list 1 for the direct prediction mode. 30. The method according to claim 27, characterized in that if the macroblock of said B-frame is used in field mode and the offset macroblock of the reference frame of List 1 is in single-frame mode, the motion vectors MV _F , _i and MV _B , _i in direct mode predictions for each i-field of the B-frame are calculated as follows: MV _{F, i} = TD _{B, i} MV / TD _D , MV _{B, i} = (TD _{B, i-} TD _D ) MV / TD _D , or Z = TV _{B, i} · 256 / TD _D , MV _{F, i} = (Z · MV + 128) >> 8, W = Z-256, MV _{B, i} = (W · MV + 128) >> 8, where TD _B , _i is the time interval between the current B-field and the reference field of list 0, which is assigned a positive sign (+) if this interval is measured from the B-field, or a negative sign (-) if this interval is measured from the reference field list 0; TD _D is the time interval between the reference frame of list 1 and the reference frame of list 0, which is assigned a positive sign (+) if this interval is measured from the reference frame of list 1, or a negative sign (-) if this interval is measured from the reference frame of list 0 ; MV is the motion vector of the offset block in the reference frame of list 1 for the direct prediction mode. 31. The method according to item 27, wherein if the macroblock of said B-frame is used in single-frame mode, the offset macroblock of said reference frame of list 1 is used in field mode, and the reference frame of list 1 follows in time after said B-frame, The motion vectors MV _F and MV _{B of the B} -frame are calculated according to the following equations, in which the information about the motion of the displaced block in field 0 of the reference frame of List 1 is used to calculate the motion vectors in direct prediction mode: MV _F = TD _B MV ₀ / TD _{D, 0} , MV _B = (TD _B -TD _{D, 0} ) MV ₀ / TD _{D, 0} , or Z = TV _B 256 / TD _{D, 0} , MV _F = (Z MV ₀ +128) >> 8, W = Z-256, MV _B = (WV MV _{0 +} 128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of list 0, which is assigned a positive sign (+) if this interval is measured from the B-frame, or a negative sign (-) if this interval is measured from the reference field of list 0 ; TD _D , ₀ - time interval between field 0 of the reference frame of list 1 and the reference field of list 0, which is assigned a positive sign (+) if this interval is measured from field 0 of the reference frame of list 1, or a negative sign (-) if this interval measured from the reference field of list 0; MV ₀ is the motion vector of the displaced block in field 0 of the reference frame of list 1 for the direct prediction mode. 32. The method according to item 27, wherein if the macroblock of said B-frame is used in single-frame mode, the offset macroblock of said reference frame of list 1 is used in field mode, and said reference frame of list 1 is preceded by time of said B-frame, The motion vectors MV _F and MV _{B of the B} -frame in direct prediction mode are calculated according to the following equations, in which information about the motion of the displaced block in field 1 of the reference frame of list 1 is used to calculate motion vectors in direct prediction mode: MV _F = TD _B MV ₁ / TD _{D, 1} , MV _B = (TD _B -TD _{D, 1} ) MV ₁ / TD _{D, 1} , or Z = _B · TV 256 / TD _{D, 1,} MV _F = (Z · MV ₁ + 128) >> 8, W = Z-256, MV _B = (W · MV ₁ +128) >> 8, where TD _B is the time interval between the current B-frame and the reference frame of list 0, which is assigned a positive sign (+) if this interval is measured from a B-frame, or a negative sign (-) if this interval is measured from a reference frame of list 0 ; TD _D , ₁ - time interval between field 1 of the reference frame of list 1 and the reference field of list 0, which is assigned a positive sign (+) if this interval is measured from field 1 of the reference frame of list 1, or a negative sign (-) if this interval measured from the reference field of list 0; MV ₁ is the motion vector of the offset block in field 1 of the reference frame of list 1 for the direct prediction mode. 33. The method of determining the motion vectors of the B-frame (bidirectional prediction frame) in the direct prediction mode in the coding system of the moving image to obtain the motion vectors of the B-frame in the direct prediction mode, namely, if the offset macroblock in the reference frame of list 1 for direct prediction mode is used in the intraframe mode, then the prediction and determination of the reference frames of lists 0 and 1 and motion vectors using neighboring blocks of the macroblock of the said B-frame, to be encoded, based on spatial redundancy, and the motion vectors of said B-frame are determined in the direct prediction mode. 34. The method according to p. 33, characterized in that if neighboring blocks A, B and C of said macroblock to be encoded belong to different reference frames, then the reference frame with the lowest index is selected as the said reference frame for each list. 35. The method according to p. 33, characterized in that if at least two neighboring blocks of the specified macroblock to be encoded belong to a reference frame with the same index, then this reference frame is selected as said reference frame for each list . 36. The method according to p. 33, characterized in that the value 0 is set for the motion vectors of lists 0 and 1, if any of the neighboring blocks A, B and C of said macroblock to be encoded is used in the intraframe mode, the motion vector is selected having the same direction as the time direction of the reference frame for each list from the neighboring block, and get the mentioned motion vector for each list by performing an averaging operation or select only one of two motion vectors from this block, e If the neighboring unit has two motion vectors with the same directions, and get the mentioned motion vector for each list by performing an averaging operation, taking into account the selected motion vector. 37. The method according to p. 33, characterized in that if it is not possible to obtain a valid reference frame index for the mode of each list, then set the value 0 for the indices of the reference frames of lists 0 and 1 and set the value 0 for said motion vector for each mode list.