Patent Publication Number: US-2022233371-A1

Title: Small electric vehicle

Description:
CROSS REFERENCE TO RELATED APPLICATION 
     The present application claims priority of Japanese Patent Application No. 2021-012218 filed Jan. 28, 2021. The entire contents of which are hereby incorporated by reference. 
     TECHNICAL FIELD 
     The present invention relates to a small electric vehicle. 
     BACKGROUND 
     Small electric vehicles, including cart-type electric rollators and electric wheelchairs for users having difficulty in walking, such as the elderly, have been publicly known. For example, JP 2014-064620 discloses a small electric vehicle (electric wheelchair) that includes left and right motors that individually drive respective left and right driving wheels, and is configured such that the numbers of revolutions of left and right motors are determined from an operation position of joystick-type operation means, the vehicle goes forward when an operation element is tilted forward, it turns when the piece is tilted obliquely forward, it turns about a fixed position when the piece is tilted obliquely backward, and it stops when the piece is tilted straight backward. 
     SUMMARY 
     As for the small electric vehicle as described above, the speed (speed difference between left and right) is determined by the operation position of the joystick-type operation element. Accordingly, in a case of turning at a slow speed, the operation element is required to be held at an intermediate operation position, which leads to a problem for a user to drive at an intended speed on a route. Furthermore, a road inclination is not taken into consideration. In a case in which motors are selected on the basis of flat ground travel, there is a possibility that the torque is insufficient for climbing, and the operability is degraded in comparison with operation on flat ground. Conversely, in a case in which the motors are increased in size for going up inclined slopes, there is a problem of increase in vehicle weight. 
     The present invention has been made in view of the points of the prior art described above, and has an object to provide a small electric vehicle that can achieve travel control suitable for road inclinations, such as on flat roads and going up upwardly inclined roads, and turning characteristics depending on the driving state, through an intuitive operation on the joystick-type operation element. 
     To solve the problems, a small electric vehicle according to the present invention includes: 
     a vehicle body that has a forward and backward direction, and a width direction; 
     left and right driving wheels provided apart in the width direction of the vehicle body; 
     free wheels provided apart from the left and right driving wheels in the forward and backward direction of the vehicle body; 
     left and right motors connected so as to respectively transmit power to the left and right driving wheels; 
     left and right rotation speed sensors for detecting rotation speeds of the left and right motors; 
     an inclination sensor for detecting an inclination of the vehicle body as a pitch angle corresponding to a component in the forward and backward direction, and a roll angle corresponding to a component in the width direction; 
     an operation unit that includes a joystick-type operation element; and 
     a control unit that controls the left and right motors according to an amount of operation on the operation element, 
     wherein the control unit is configured to calculate target rotation speeds of the left and right motors, based on a target vehicle speed provided by an inclination angle in consideration of the pitch angle and the roll angle detected through the inclination sensor and by an operation position of the operation element, and on a target vehicle angular velocity provided by the inclination angle, by the operation position and by the actual speed of the vehicle, and control the left and right motors such that actual rotation speeds of the left and right motors follow the respective target rotation speeds. 
     The small electric vehicle according to the present invention is configured as described above. Accordingly, the inclination in the forward and backward direction (pitch angle) and the inclination in the width direction (roll angle) that affect the travel of the small electric vehicle can be reflected, as an integrated inclination angle (λ), in travel control. The speed can be controlled and the acceleration/deceleration characteristics can be changed depending on the inclination angle, and the turning characteristics can be changed depending on the inclination angle and the actual speed. The acceleration/deceleration characteristics and the turning characteristics that support the road inclination and the travel state can be obtained only by an intuitive operation on a joystick-type operation element. The characteristics are effective in improving simplification of the operation and the usability. Furthermore, the loads on the vehicle body system and motors are reduced, which is advantageous in reducing the weight of vehicle body and the manufacturing cost. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a side view showing a small electric vehicle. 
         FIG. 2  is a block diagram showing a control system of the small electric vehicle. 
         FIG. 3  is a block diagram showing left and right motor control according to a first embodiment. 
         FIG. 4  is a block diagram showing left and right motor control according to a second embodiment. 
         FIG. 5  is a block diagram showing left and right motor control according to a third embodiment. 
         FIG. 6  is a target vehicle speed map depending on the inclination angle (λ) through the joystick operation. 
         FIG. 7( a )  shows a target angular velocity map for low speed, depending on the inclination angle (λ) through joystick operations. 
         FIG. 7( b )  shows a target angular velocity map for high speed depending on the inclination angle (λ) through joystick operations. 
         FIG. 8  shows a target vehicle acceleration map depending on the inclination angle (λ) and actual speed. 
         FIG. 9  shows a target vehicle angular acceleration map depending on the inclination angle (λ) and actual speed. 
         FIG. 10  shows a target vehicle deceleration map depending on the inclination angle (λ) and actual speed. 
         FIG. 11  shows a target vehicle angular deceleration map depending on the inclination angle (λ) and actual speed. 
         FIG. 12  shows a target vehicle rapid deceleration map depending on the inclination angle (λ) and actual speed during rapid stop control. 
     
    
    
     DETAILED DESCRIPTION 
     Hereinafter, embodiments of the present invention are described in detail with reference to the drawings. 
     In  FIG. 1 , an electric vehicle  1  according to an embodiment of the present invention includes a vehicle body  2  made up of a mobile base  21  (lower traveling body), and an upper frame  22  provided to stand from a rear part (rear-side base  24 ) of the mobile base  21 , and is usable in a small electric vehicle mode (riding mode  1 ) indicated by solid lines in the diagram, and in a rollator mode ( 1 ′) indicated by chain double-dashed lines in the diagram. 
     The mobile base  21  includes: the rear-side base  24  (main body part) provided with left and right driving wheels  4  (rear wheels), and the upper frame  22 ; and a front-side base  25  provided with left and right driven wheels  5  (front wheels). The front-side base  25  is joined to the front side of the rear-side base  24  slidably in the front and rear direction. The mobile base  21  is configured such that the wheelbase is expandable and contractible. 
     The left and right driving wheels  4  are independently driven respectively by left and right motor units  40  ( 40 L and  40 R) mounted on the rear-side base  24 . The left and right driven wheels  5  is made up of free wheels (omni wheels, or omnidirectional wheels) including many rotatable rollers  50  at grounding parts around axes in circumferential directions. As described later, the electric vehicle  1  can be steered, braked, and driven only by controlling the left and right motor units  40 L and  40 R. 
     The upper frame  22  have an inverted U form or a gate shape formed by joining upper ends of a pair of left and right side frames provided to stand upward from both the left and right sides of the rear-side base  24 , with an upper end frame extending in the vehicle width direction. A lower end part of a stem  31  of a rear handle  3  is rigidly coupled to a coupling part  23  at the center of the upper end frame in the vehicle width direction, and a seat backrest  6  is supported at the coupling part  23 . 
     The rear handle  3  is formed in a T-bar shape that has a pair of grip parts extending left and right from a connection portion  32  with the upper end of the stem  31 . At the left and right grip parts of the rear handle  3 , grip sensors  30  that detect a state of gripping (hands on) by a user (or a helper) are provided. Touch sensors, such as capacitance sensors or pressure-sensitive sensors, can be used as the grip sensors  30 . The left and right grip parts of the rear handle  3  serve as an operation unit in a case of use by the user himself or herself in the rollator mode ( 1 ′), and in a case in which the helper or the like operates the electric vehicle in a case in which the user is seated on the seat  7 . Note that although omitted in  FIG. 1 , an electromagnetic brake release switch  34 , and a speaker  35  are provided on the connection portion  32  at the center of the rear handle  3 . 
     Base parts of support frames  81  for armrests  82  are fixed at bent parts at the middle of the upper frame  22  (side frames) in the height direction. A joystick  83 , which constitutes a riding mode operation unit  8 , is provided at a front end part of the armrest  82  on the right side, which is a deeper side in the  FIG. 1 . A display unit  80  and a travel permission switch  84  are provided on an upper surface of the grip part having the same shape at a front end part of the armrest  82  on the left side, which is a near side in  FIG. 1 . 
     A two-axis joystick that can be tilted to the front, rear, left, and right, and allows an output to be obtained depending on a tilted angle, or a multi-axis joystick involving this function may be used as the joystick  83 . A non-contact joystick that uses a Hall sensor is preferable. The joystick  83  is configured such that an urging force (a restoring force or an operational reaction force) toward a neutral position depending on the tilted angle is applied, by an urging member (spring, etc.), not shown. In a state in which no operational force is applied, that is, a state in which the hand of the user is off the joystick  83 , the joystick returns by itself to the neutral position. Control of the left and right motor units  40  ( 40 L and  40 R) through an operation on the joystick  83  is described later. 
     At a pivot support part  27  that protrudes forward from the bent parts of the upper frame  22  (side frames), support frames  71  for the seat  7  (seat cushion) are pivotably supported by a shaft  7   a  in the vehicle width direction. In addition, the lower ends of the support frames  71  are rotatably and slidably joined to the front-side base  25  (pins) via the joining parts  7   b  (slots). 
     According to the configuration described above, when the seat  7  at a seating position is turned downward ahead from the riding mode ( 1 ), indicated by the solid lines in the diagram, to a folded position ( 7 ′) as indicated by chain double-dashed lines in the diagram, the front-side base  25  is slid backward in an interlocking manner, the mobile base  21  is shortened, and the mode becomes a rollator mode ( 1 ′), which allows user operation while standing and walking with the rear handle  3  being gripped. 
     Conversely, when the seat ( 7 ′) at the folded position is moved from the rollator mode ( 1 ′) to the seating position  7  by turning upward behind, the front-side base  25  slides forward, the mobile base  21  is elongated, and the mode becomes the riding mode ( 1 ). In this state, an upper surface  25   b  of the front-side base  25  moved ahead of a tray  24   b  can be used as a footrest for a passenger. 
     Note that locking mechanisms (locking pins or the like urged by urging members, such as springs) that lock the front-side base  25  at each of an elongated position and a shortened position are provided in the mobile base  21 , where a vehicle state detection sensor  28  (mechanical switch etc.) that detects the locked state in each position is attached. Furthermore, urging members (springs, etc.) for urging toward the intermediate position (in a release direction) at each of the elongated position and the shortened position are provided. Release tags  26  joined to the locking mechanisms through Bowden cables are provided at upper end portions of the support frames  71 . 
     Accordingly, the configuration is made such that when the release tags  26  are pulled at either of the elongated position and the shortened position, the locking mechanisms are released, the vehicle body  2  is at the intermediate position by being urged by the urging members, and when from this state the seat  7  (support frames  71 ) is turned forward or backward from the intermediate position against urging by the urging members, and the locking mechanisms are locked at either of the elongated position and the shortened position of the front-side base  25 . 
       FIG. 2  is a block diagram showing a control system of the electric vehicle  1 . The electric vehicle  1  includes a battery  9  that supplies power to the left and right motor units  40  ( 40 L and  40 R), and a control unit  10  that controls the left and right motor units  40  ( 40 L and  40 R). The control unit  10  has an interlock function of executing control for each of the riding mode ( 1 ) and the rollator mode ( 1 ′) in the locked state at the corresponding position detected by the vehicle state detection sensor  28 . 
     In the riding mode ( 1 ), the grip sensors  30  are disabled, the control unit  10  is configured to control the speeds of the left and right motor units  40  ( 40 L and  40 R) on the basis of a control map, described later, in response to an operation (the amount of operation, and operation direction) on the joystick  83 , which constitutes the riding mode operation unit  8 , when the travel permission switch  84  is turned on, and allow drive operations that include going forward, backward, turning, and braking and stopping of the electric vehicle  1 . Note that when an inclination equal to or greater than a predetermined threshold is detected by an inclination sensor  20 , the target speed is corrected in consideration of the gravity (load) applied depending on the inclination. 
     On the other hand, in the rollator mode ( 1 ′), the riding mode operation unit  8  is disabled, the control unit  10  controls the torques of the left and right motor units  40  ( 40 L and  40 R) on the basis of detection information from the inclination sensor  20 , the left and right rotation speed sensors  43  and the like and of a predetermined control map. Note that when an inclination equal to or greater than a predetermined threshold is detected by the inclination sensor  20 , a compensation torque for compensating for the gravity (load), which is applied depending on the inclination, is superimposed on the torque command value. The grip sensor  30  only detects a grip (hands on/off) on the rear handle  3  by the user, and is not involved in the torque control of the motor units  40 . 
     The control unit  10  includes: a computer (microcomputer) made up of a ROM that stores a program and data for executing control in each of the modes, a RAM that temporarily stores a computation processing result, a CPU that performs computation processes and the like; and a power source circuit that includes drive circuits (motor drivers) for the left and right motors  41 , and a relay that turns the power of the battery  9  on and off. 
     The left and right motor units  40  ( 40 L and  40 R) each include a motor  41 , an electromagnetic brake  42  that locks the rotor of the corresponding motor  41 , and a rotational position sensor ( 43 ) that detects the rotational position of the corresponding motor  41 . Drive shafts of the motors  41  are connected to the respective driving wheels  4  ( 4 L and  4 R) via reduction gears, not shown, in a power-transmissible manner. 
     The left and right motors  41  are made up of brushless DC motors that switch the currents in coils in corresponding phases in the drive circuits to support the phases of rotors detected by the rotational position sensors ( 43 ). In the riding mode ( 1 ), the rotational position sensors (Hall sensors) are used as vehicle speed sensors ( 43 ) that detect the actual speed of the electric vehicle  1 . In the rollator mode ( 1 ′), the rotational position sensors are used as the rotation speed sensors  43 . 
     The drive circuits for the left and right motors  41  include current sensors that detect coil currents. The coil currents correspond to the torques of the left and right motors  41 . The control unit  10  executes the torque control of the left and right motors  41  by controlling the coil currents through PWM control (pulse width modulation control) or the like. 
     Preferably, the electromagnetic brakes  42  are negative actuated type electromagnetic brakes that lock the drive shafts of the motors  41  in an unexcited state, and release the locking in an excited state. By adopting the negative actuated type electromagnetic brakes, the electric vehicle  1  can be securely stopped when the key is turned off or at a stop without consuming power. 
     On the other hand, to cause the locks of the electromagnetic brakes  42  to be released and allow the electric vehicle  1  to be movable in case of urgency or emergency, for example, in a case in which it is intended to move the electric vehicle  1  without using the power of the motors  41 , or in an undrivable case due to reduction in remaining battery charge, the electromagnetic brake release switch  34  is provided as forcible release means for the electromagnetic brakes  42 . The electromagnetic brake release switch  34  is provided adjacent to the grip part of the rear handle  3 , but is operable irrespective of detection of gripping of the grip sensor  30 . 
     The inclination sensor  20  is implemented on a circuit board of the control unit  10  mounted in the mobile base  21  (rear-side base  24 ) of the vehicle body  2 . A two-axis inclination sensor or an acceleration sensor that detects the inclination in the front and rear direction of the vehicle body  2  (pitch angle P) and the inclination in the lateral direction (roll angle R), or a multi-axis inertial sensor where an angular acceleration sensor (gyroscope sensor) is additionally integrated with the aforementioned sensor is usable. 
     (Travel Control in Riding Mode) 
     According to the electric vehicle  1  configured as described above, in the riding mode ( 1 ), the rotation speeds of the left and right motors  41  ( 40 L and  40 R) are controlled based on an operation (an amount of operation and an operation direction) of the joystick  83  by the user. However, the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) are not immediately determined from the operation position of the joystick  83 . Instead, according to an inclination angle λ in consideration of the pitch angle P and the roll angle R detected by the inclination sensor  20 , the target vehicle speed (straight travel speed) based on the operation position of the joystick  83 , and the target vehicle angular velocity based on the left and right direction components of the operation position of the joystick  83  are separately calculated. Based on them, the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the rotation speeds of the left and right driving wheels  4  ( 4 L and  4 R) are calculated. 
     The inclination angle λ is calculated by, for example, the following expression 1. 
       λ=| P|+|R|   (Expression 1)
 
     The electric vehicle  1 , which assumes travel on a sidewalk, changes the direction or turns on an inclined surface in some cases other than cases of traveling on an upwardly sloping road along the direction of a track. In such cases, not only the inclination (pitch angle P) in the forward and backward direction of the vehicle body  2 , but also the inclination (roll angle R) in the width direction affects the behavior of the vehicle. 
     In particular, in a case of climbing on an inclined surface in an oblique direction on the inclined surface, or in a case of turning while climbing on the inclined surface, the pitch angle P is smaller in comparison with a case of direct climbing on the inclined surface. However, the loads on the left and right motors  41  ( 40 L and  40 R) and the load on the posture of the user are heavier by the amount of the roll angle. Likewise, even in a case of traveling downhill on an inclined surface in an oblique direction on the inclined surface, or in a case of turning while traveling downhill on the inclined surface, the pitch angle P is smaller in comparison with a case of direct traveling downhill on the inclined surface. However, the loads on the left and right motors  41  ( 40 L and  40 R) are heavier. The user feels that the behavior of the vehicle is abrupt. 
     Accordingly, in a case with a road inclination, in particular, in a case with the inclination (roll angle R) in the width direction in addition to the inclination (pitch angle P) in the forward and backward direction of the vehicle body  2 , when control is performed according to the target vehicle speed and the target vehicle angular velocity identical to those on a flat road, the loads on the left and right motors  41  ( 40 L and  40 R) as well as the load on the user become heavy. 
     For evaluating such an inclination in consideration of the traveling direction of the vehicle  1  with respect to the inclined surface, it is confirmed, through a driving test, that by obtaining the inclination angle λ through an addition equation, such as the expression 1, an indicator of the road inclination and the vehicle inclination in conformity with the actual situation is obtained. 
     Hereinafter, embodiments of control (hereinafter called lambda control) that changes the target vehicle speed and the target vehicle angular velocity depending on the inclination angle λ are described with reference to the drawings. 
     First Embodiment 
       FIG. 3  is a block diagram showing left and right motor control according to a first embodiment in consideration of the inclination angle λ. As shown in the diagram, a target vehicle speed calculation block  110  uses not only an input of the front and rear direction on the joystick  83  but also an input of the left and right direction. Furthermore, the inclination angle λ is also considered. Accordingly, speed control different from that during straight traveling, for example, traveling at a reduced speed, can be executed during turning depending on the road inclination and the traveling direction of the vehicle, without particular consideration for traveling at a reduced speed. 
     Not only a left and right direction input on the joystick  83  and the inclination angle λ, but also the vehicle actual speed during operation, is reflected in a target vehicle angular velocity calculation block  120 . Accordingly, the turning characteristics can be changed depending on the road inclination and the traveling speed of the electric vehicle  1 . 
     In the block diagram of  FIG. 3 , based on the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle speed v calculated by the target vehicle speed calculation block  110 , and on the difference between the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle angular velocity ω calculated by the target vehicle angular velocity calculation block  120 , the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) are calculated in a left and right motor target rotation speed calculation block  130 . 
     Furthermore, in the left and right motor required torque calculation block  150 , based on the actual rotation speeds of the left and right motors  41  ( 40 L and  40 R) detected by the left and right rotation speed sensors  43 , and on the target rotation speeds of the left and right motors  41  ( 40 L and  40 R), the required left and right motor torques are calculated by feedback control (e.g., PID control) that causes the actual rotation speeds of the left and right motors  41  ( 40 L and  40 R) to follow the respective target rotation speeds. Based on these, current control for the left and right motors  41  ( 40 L and  40 R) is executed. 
     When the inclination sensor  20  detects a vehicle inclination (the pitch angle P and the roll angle R) equal to or greater than a predetermined threshold, a compensation torque calculation block  140  calculates a compensation torque in a direction of compensating for the climbing/traveling downhill load applied depending on the pitch angle P and/or the lateral direction load applied depending on the roll angle R, and superimposes the torque on the left and right motor required torques calculated by the left and right motor required torque calculation block  150 . 
     (Target Vehicle Speed Map) 
       FIG. 6  shows a target vehicle speed map for target vehicle speed calculation ( 110 ) by a joystick operation. In the diagram, solid lines for the front and rear amount of operation and the left and right amount of operation indicate the target vehicle speed map in a case in which the inclination angle λ=λ 0  (zero inclination), and broken lines indicate the target vehicle speed map in a case in which the inclination angle λ=λm (set maximum inclination angle). 
     These target vehicle speed maps are stored as a look-up table in a ROM area of the control unit  10 . When the inclination angle λ given by the expression 1 described above is zero degrees or less than a predetermined threshold λ 1  (e.g., three degrees) that can be substantially assumed as a flat land, the target vehicle speed map with the inclination angle λ=λ 0  is applied. When the inclination angle λ is equal to or greater than the set maximum inclination angle, the target vehicle speed map with the inclination angle λ=λm is applied. 
     When the inclination angle λ is equal to or greater than the predetermined threshold λ 1  and less than the set maximum inclination angle λm, calculation is performed using a conversion equation for proportional distribution as in the following expression 2, from an output value X 0  based on the target vehicle speed map in the case with the inclination angle λ=λ 0 , and an output value λm based on the target vehicle speed map in the case with the inclination angle λ=λm. 
         X=X 0+(λ−λ1)*( Xm−X 0)/(λ m−λ 1)  (Expression 2)
 
     In  FIG. 6 , according to the target vehicle speed map that has the inclination angle λ=λ 0  and serves as the basis, when the operation position of the joystick  83  is in a forward region F 1  including the front end in the operation range, a target forward speed va is designated. When the position in a backward region B 1  including the rear end, a target backward speed vb is designated. When the operation position of the joystick  83  is in any of left and right side regions F 2  including the left and right ends, a target forward speed vc is designated. When the position in a center region n including the center (neutral position), stopping (a target speed of zero) is designated. 
     As indicated in maps on the right side and the lower side in  FIG. 6 , the target forward speed va in the forward region F 1  is higher than the target forward speed vc in the left and right side regions F 2 . The target forward speed vc in the left and right side regions F 2  has a greater (or equal) absolute value than the target backward speed vb in the backward region B 1  has. For example, according to the map with the inclination angle λ=λ 0 , the target forward speed va can be 3 to 5 km/h, the target forward speed vc can be 1 to 2 km/h, and the target backward speed vb can be 1 km/h. 
     Furthermore, in  FIG. 6 , transition regions F 3  and F 4  where the target forward speed increases from the center region n toward the forward region F 1  and the left and right side regions F 2  are provided between the center region n and the forward region F 1 , and between the center region n and the left and right side regions F 2 . A transition region B 2  in which the target backward speed increases from the center region n toward the backward region B 1  is provided between the center region n and the backward region B 1 . When the operation position of the joystick  83  is in the transition region F 3  or the transition region B 2 , an intermediate target forward speed or an intermediate target backward speed is designated. 
     Consequently, not only when the joystick  83  is operated to the forward region F 1  (and its transition region F 3 ) but also when the joystick  83  is operated to any of the left and right side regions F 2  (and its transition region F 4 ), the target forward speed vc is designated, thereby allowing the forward rotation to be output even when a target vehicle angular velocity ±ω from a target vehicle angular velocity calculation  120  block, described later, is input. 
     This is because the lateral movement of free wheels  5  made up of omni wheels is achieved by the rotation of the rollers  50 , and the start performance and the step traveling performance are lower than those during straight traveling, and accordingly, the load on the system is reduced by preventing pivot turn (spin turn) due to an intuitive turning operation. Note that when the joystick  83  is operated obliquely backward FB, the target speed is zero at the middle between the left and right side regions F 2  and the backward region B 1 . Pivot turn (spin turn) can be achieved at a narrow place, such as in a room or an elevator entrance. 
     According to the target vehicle speed map in the case with the inclination angle λ=λm indicated by the broken lines in  FIG. 6 , a target forward speed vam when the operation position of the joystick  83  is in the forward region F 1 , and a target forward speed vcm when the position is in any of the left and right side regions F 2  are designated to have a smaller value in comparison with the case with inclination angle λ=λ 0 . 
     For example, according to the target vehicle speed map with the inclination angle λ=λm, the target forward speed vam can be 2 to 3 km/h, and the target forward speed vcm can be 0.5 to 1 km/h. In addition, the target backward speed vb when the operation position of the joystick  83  is in the backward region B 1  may have the same value (e.g., 1 km/h) as in the case with the inclination angle λ=λ 0 . 
     As described above, it is advantageous, according to the lambda control, that changes the target forward speed va to vam and vc to vcm depending on the inclination angle λ, the target forward speed is set to have a relatively small value during inclined travel, the load on the user due to the behavior of the vehicle  1  is reduced, and the loads on the left and right motors  41  ( 40 L and  40 R) (required specifications) are reduced. 
     (Target Vehicle Angular Velocity Map) 
     Next,  FIG. 7  shows a target vehicle angular velocity map for target vehicle angular velocity calculation ( 120 ) through joystick operation. The target vehicle angular velocity map includes: a target vehicle angular velocity map for low speed (a) that defines the target vehicle angular velocity when the actual speed is in a low speed region or a speed of zero; and a target vehicle angular velocity map for high speed (b) that defines the target vehicle angular velocity when the actual speed is at the maximum speed or in a predetermined high speed region in the setting speed region for the vehicle. 
     These target vehicle angular velocity maps (a) and (b) each define a target vehicle angular velocity map (solid lines) when the inclination angle λ=λ 0  (zero inclination), and a target vehicle angular velocity map (broken lines) when the inclination angle λ=λm (set maximum inclination angle). Both are stored as a look-up table in the ROM area of the control unit  10 . 
     When the inclination angle λ given by the expression 1 described above is zero degrees or less than the predetermined threshold λ 1  (for example, three degrees), which can be substantially assumed to be flat land, the target vehicle angular velocity map with the inclination angle λ=λ 0  is applied. When the inclination angle λ is equal to or greater than the set maximum inclination angle λm (e.g., 10 degrees), the target vehicle angular velocity map with the inclination angle λ=λm is applied. When the inclination angle λ is equal to or greater than the predetermined threshold λ 1  and less than the set maximum inclination angle λm, calculation is performed using the conversion equation of the expression 2 described above, from the output value λ 0  based on the target vehicle angular velocity map with the inclination angle λ=λ 0  and the output value λm based on the target vehicle angular velocity map with the inclination angle λ=λm. 
     According to the target vehicle angular velocity map for low speed (a) with the inclination angle λ=λ 0  indicated by the solid lines in  FIG. 7 , the target vehicle angular velocity co is designated when the operation position of the joystick  83  is in left and right side regions T 1  including the left and right ends in the operation range, and the target vehicle angular velocity of zero is designated when the position is in a center region n 1  including the center (neutral position). Transition regions T 3  in which the target vehicle angular velocity ω gradually increases from the center region n toward the left and right side regions T 1  are provided between the center region n 1  and the left and right side regions T 1 . 
     Likewise, according to the target vehicle angular velocity map for high speed (b) with the inclination angle λ=λ 0 , the target vehicle angular velocity ω 2  is designated when the operation position of the joystick  83  is in left and right side regions T 2  including the left and right ends in the operation range, and the target vehicle angular velocity of zero is designated when the position is in a center region n 2  including the center (neutral position). Transition regions T 4  in which the target vehicle angular velocity ω gradually increases from the center region n 2  toward the left and right side regions T 2  are provided between the center region n 2  and the left and right side regions T 2 . 
     Here, the maximum target vehicle angular velocity ω 2  in the left and right side regions T 2  in the target vehicle angular velocity map for high speed (b) is higher than the maximum target vehicle angular velocity ω 1  in the left and right side regions T 1  in the target vehicle angular velocity map for low speed (a), and the center region n 2  in the target vehicle angular velocity map for high speed (b) is narrower than the center region n 1  in the target vehicle angular velocity map for low speed (a). The transition regions T 4  in the target vehicle angular velocity map for high speed (b) are wider than the transition regions T 3  in the target vehicle angular velocity map for low speed (a). 
     According to a preferable embodiment, the target vehicle angular velocity map for low speed (a) corresponds to a case in which the actual speed of the vehicle is equal to or less than 0.5 km/h, which can be substantially assumed as zero. The target vehicle angular velocity map for high speed (b) corresponds to a case in which the actual speed of the vehicle is 4.5 km/h. The maximum target vehicle angular velocity ω 1  in the left and right side regions T 1  in the target vehicle angular velocity map for low speed (a) with the inclination angle λ=λ 0  is 60 degrees per second (1.05 rad/s). The maximum target vehicle angular velocity ω 2  in the left and right side regions T 2  in the target vehicle angular velocity map for high speed (b) in the case with the inclination angle λ=λ 0  is 90 degrees per second (1.57 rad/s) to 120 degrees per second (2.09 rad/s). 
     In a case with the inclination angle λ=λm indicated by the broken lines in  FIG. 7 , a smaller value than that in the case with the inclination angle λ=λ 0  is designated as a target vehicle angular velocity ω 1   m  in the target vehicle angular velocity map for low speed (a), and a target vehicle angular velocity ω 2  in the target vehicle angular velocity map for high speed (b), when the operation position of the joystick  83  is in any of the left and right side regions T 1 . For example, 30 degrees per second (0.52 rad/s) are designated as the target vehicle angular velocity ω 1   m  in the case with the inclination angle λ=λm, and 60 degrees per second (1.05 rad/s) are designated as the target vehicle angular velocity ω 2   m.    
     Note that instead of setting of the transition regions T 4 , in which the target vehicle angular velocity continuously changes depending on the operation position of the joystick  83 , between the left and right side regions T 2  and the center region n 2 , a region with an intermediate target vehicle angular velocity of for example, 90 degrees per second (1.57 rad/s) may be set. 
     The control unit  10  calculates the actual speed of the electric vehicle  1  on the basis of the actual rotation speeds of the left and right motor units  40  ( 40 L and  40 R) detected by the respective rotation speed sensors  43 . Depending on the vehicle actual speed and the inclination angle λ, the target vehicle angular velocity map for low speed (a) or the target vehicle angular velocity map for high speed (b) is selectively applied. Alternatively, when the actual speed is in an intermediate speed region between the low speed region and the high speed region, the target vehicle angular velocity corresponding to the actual speed and the inclination angle λ are calculated from the target vehicle angular velocity map for low speed (a) and the target vehicle angular velocity map for high speed (b). 
     For example, if first and second, two-step, speed thresholds are configured, and the map is switched to the target vehicle angular velocity map for high speed (b) when the actual speed becomes equal to or greater than the second speed threshold (e.g., 2.5 km/h) from the low speed region during application of the target vehicle angular velocity map for low speed (a), and the map is switched to the target vehicle angular velocity map for low speed (a) when the actual speed becomes less than the first speed threshold (e.g., 1.5 km/h) lower than the second speed threshold during application of the target vehicle angular velocity map for high speed (b), the map switching frequency can be reduced and stable control can be performed. 
     It may be configured such that when the target vehicle angular velocity corresponding to the actual speed is calculated from the target vehicle angular velocity map for low speed (a) and the target vehicle angular velocity map for high speed (b), a target vehicle angular velocity may be designated to which target vehicle angular velocity designation values in the target vehicle angular velocity map for low speed (a) and the target vehicle angular velocity map for high speed (b) are proportionally distributed depending on the rate of the current actual speed to the actual speed corresponding to the target vehicle angular velocity map for high speed (b). 
     According to the configuration of applying the target vehicle angular velocity map for low speed (a) and the target vehicle angular velocity map for high speed (b) depending on the actual speed and the inclination angle λ as described above, the following turning characteristics can be obtained. 
     That is, when the electric vehicle  1  is substantially in a stop state (the actual speed is in the low speed region or the speed of zero), the relatively large center region n 1  (insensitive zone) is set on both the left and right sides of the neutral position of the joystick  83 . Even if the user operates the joystick  83  to the left or right in this range, the electric vehicle  1  does not start to move. Accordingly, as described above, immediate transition from the substantially stop state to the turning motion is prevented, and only when the user clearly intentionally operates the joystick  83  to any of the left and right side regions T 1 , forward traveling or turning is started. 
     On the other hand, when the actual speed of the electric vehicle  1  is in a high speed region, for example, when the user operates the joystick  83  forward and the vehicle is in a forward travelling state, the transition regions T 4  are set adjacent to the left and right sides of the neutral position. By the user operating the joystick  83  from the forward tilted position to the left or right, traveling in a desired direction can be achieved while finely adjusting the course, and the steerable performance fairly corresponding to the straight travel speed of the electric vehicle  1  can be obtained. 
     It is advantageous that, according to the lambda control that changes the target vehicle angular velocities ω 2  to ω 2   m  and ω 1  to ω 1   m  depending on the inclination angle λ, the target vehicle angular velocity be set to have a relatively small value during inclined travel, the load on the user due to the turning behavior of the vehicle  1  is reduced, and the loads on the left and right motors  41  ( 40 L and  40 R) (required specifications) are reduced. 
     Second Embodiment 
     According to the first embodiment described above, the case in which the target vehicle speed v and the target vehicle angular velocity ω are changed depending on the inclination angle λ has been described. By additionally changing the target vehicle acceleration a and the target vehicle angular acceleration a depending on the inclination angle λ, the behavior of the electric vehicle  1  can be further optimized. 
       FIG. 4  is a block diagram showing left and right motor control according to a second embodiment in consideration of the inclination angle λ. In comparison with the block diagram in the first embodiment shown in  FIG. 3 , a target vehicle acceleration calculation block  111  and a target vehicle angular acceleration calculation block  121  are added. 
     The target vehicle acceleration calculation block  111  receives the target vehicle speed v calculated by the target vehicle speed calculation block  110 , the vehicle actual speed, and inclination angle λ. The target vehicle acceleration a is calculated depending on the deviation between the vehicle actual speed and the target vehicle speed v and on the inclination angle λ. The target vehicle acceleration a is the rate of change of speed in control that causes the vehicle actual speed to follow the target vehicle speed v given by the front, rear, left and right input on the joystick  83  and by the inclination angle λ, and corresponds to the sensitivity of speed control. 
     In addition, the target vehicle angular acceleration calculation block  121  receives the target vehicle angular velocity ω calculated by the target vehicle angular velocity calculation block  120 , and the inclination angle λ. The target vehicle angular acceleration a is calculated depending on the deviation between the difference between the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle angular velocity ω, and the difference between the actual rotation speeds of the left and right motors  41  ( 40 L and  40 R) detected by the rotation speed sensors  43 , and on the inclination angle λ. The target vehicle angular acceleration a is the rate of change of angular velocity in control that causes the difference between the actual rotation speeds to follow the difference between the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle angular velocity ω given by the left and right input on the joystick  83 , the vehicle actual speed and the inclination angle λ, and corresponds to the sensitivity of turning control. 
     Consequently, in the block diagram in the second embodiment shown in  FIG. 4 , in the lambda control that changes the target vehicle speed v and the target vehicle angular velocity ω depending on the inclination angle λ, the sensitivities of the speed control and the turning control, i.e., the response speed, can be adjusted. 
     (Target Vehicle Acceleration Map) 
       FIG. 8  shows a target vehicle acceleration map that defines a relationship between the vehicle actual speed v and the target vehicle acceleration a for target vehicle acceleration calculation ( 111 ). Solid lines in the diagram indicate the target vehicle acceleration map in the case with the inclination angle λ=λ 0  (zero inclination). Broken lines indicate the target vehicle acceleration map in the case with the inclination angle λ=λm (set maximum inclination angle). 
     These target vehicle acceleration maps are stored as look-up tables in a ROM area of the control unit  10 . When the inclination angle λ given by the expression 1 described above is zero degrees or less than a predetermined threshold λ 1  (e.g., three degrees) that can be substantially assumed as a flat land, the target vehicle acceleration map with the inclination angle λ=λ 0  is applied. When the inclination angle λ is equal to or greater than the set maximum inclination angle, the target vehicle acceleration map with the inclination angle λ=λm is applied. 
     When the inclination angle λ is equal to or greater than the predetermined threshold λ 1  and less than the set maximum inclination angle λm, calculation is performed using the expression 2 described above, from an output value X 0  based on the target vehicle acceleration map in the case with the inclination angle λ=20, and an output value λm based on the target vehicle acceleration map in the case with the inclination angle λ=λm. 
     According to the target vehicle acceleration map shown in  FIG. 8 , when the vehicle actual speed v is zero, the maximum target vehicle accelerations a 2  and am are designated. In addition, with respect to the target vehicle acceleration a 2  (e.g., 2 km/h/s=0.56 m/s 2 ) in the case with the inclination angle λ=20, the target vehicle acceleration am (e.g., 4 km/h/s=1.11 m/s 2 ) in the case with the inclination angle λ=λm has a larger value. In each of the cases, the more the vehicle actual speed v increases, the smaller the target vehicle acceleration becomes. In the high speed region in the forward traveling direction and the backward traveling direction, a lower limit value a 1  (e.g., 1 km/h/s=0.28 m/s 2 ) is achieved. 
     That is, in a case in which the speed is zero or in the low speed region, the speed is caused to rapidly reach the target vehicle speed v. In addition, in a case of being in the state of traveling in the high speed region, abrupt change in speed is suppressed. Thus, the traveling stability is secured. 
     When the inclination angle λ is large, the target vehicle speed v calculated by the target vehicle speed calculation block  110  is set to be smaller (vam at the maximum) than that in the case of a small inclination angle λ (va at the maximum). Accordingly, only with such control based on the target vehicle speed v, it is felt that starting of the vehicle  1  in response to the operation on the joystick  83  is sluggish when the inclination angle λ is large. Accordingly, when the inclination angle λ is large, the target vehicle acceleration (am at the maximum) is set to be large instead of setting the target vehicle speed (vam at the maximum) to be small in the low speed region to increase the sensitivity of speed control, thereby allowing the operational feeling similar to that on flat land to be obtained. 
     (Target Vehicle Angular Acceleration Map) 
       FIG. 9  shows a target vehicle angular acceleration map that defines a relationship between the angular velocity ω and the target vehicle angular acceleration a for target vehicle angular acceleration calculation ( 121 ). Solid lines in the diagram indicate the target vehicle angular acceleration map in the case with the inclination angle λ=λ 0  (zero inclination). Broken lines indicate the target vehicle angular acceleration map in the case with the inclination angle λ=λm (set maximum inclination angle). 
     According to the target vehicle angular acceleration map shown in  FIG. 9 , in comparison with the target vehicle angular velocity a 1  in the case with the inclination angle λ=λ 0  (e.g., 120 degrees/s 2 =2.09 rad/s 2 ), a large target vehicle angular acceleration am (e.g., 720 degrees/s 2 =12.56 rad/s 2 ) is designated in the case with the inclination angle λ=λm. When the inclination angle λ is large, the sensitivity of turning control is increased, thereby obtaining the operational feeling similar to that on a flat land. 
     Third Embodiment 
     According to the second embodiment described above, the case in which the target vehicle speed v, the target vehicle angular velocity ω, the target vehicle acceleration a, and the target vehicle angular acceleration a are changed depending on the inclination angle λ has been described. According to a third embodiment shown in  FIG. 5 , a case is described in which a target vehicle deceleration calculation block  112  with the target vehicle speed v tending to decrease is added besides the target vehicle acceleration calculation block  111  with the target vehicle speed v tending to increase, a target vehicle angular deceleration calculation block  122  with the target vehicle angular velocity ω tending to decrease is added besides the target vehicle angular acceleration calculation block  121  with the target vehicle angular velocity ω tending to increase, thus allowing the acceleration, deceleration, angular acceleration and the angular deceleration to be individually set depending on the inclination angle λ. 
     In  FIG. 5 , the target vehicle speed v calculated by the target vehicle speed calculation block  110  depending on the inclination angle λ, the vehicle actual speed, and inclination angle λ are input into both the target vehicle acceleration calculation block  111  and the target vehicle deceleration calculation block  112 . Here, when the deviation between the vehicle actual speed and the target vehicle speed v is positive, the target vehicle acceleration calculation block  111  calculates the target vehicle acceleration a depending on the inclination angle λ. When the deviation between the vehicle actual speed and the target vehicle speed v is negative, the target vehicle deceleration calculation block  112  calculates the target vehicle deceleration d depending on the inclination angle λ. 
     In addition, in  FIG. 5 , the target vehicle angular velocity ω calculated by the target vehicle angular velocity calculation block  120  depending on the inclination angle λ, and the inclination angle λ are input into both the target vehicle angular acceleration calculation block  121  and the target vehicle angular deceleration calculation block  122 . Here, when the deviation between the difference between the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle angular velocity ω, and the difference between the actual rotation speeds of the left and right motors  41  ( 40 L and  40 R) detected by the rotation speed sensors  43  is positive, the target vehicle angular acceleration calculation block  121  calculates the target vehicle angular acceleration a depending on the inclination angle λ. When the deviation between the difference between the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle angular velocity ω, and the difference between the actual rotation speeds of the left and right motors  41  ( 40 L and  40 R) detected by the rotation speed sensors  43  is negative, the target vehicle angular deceleration calculation block  122  calculates the target vehicle angular deceleration δ depending on the inclination angle λ. 
     Consequently, in addition to the target vehicle speed v calculated by the target vehicle speed calculation block  110 , and the target vehicle angular velocity ω calculated by the target vehicle angular velocity calculation block  120 , the target vehicle acceleration a or the target vehicle deceleration d depending on the inclination angle λ, and the target vehicle angular acceleration a or the target vehicle angular deceleration δ depending on the inclination angle λ are input into the left and right motor target rotation speed calculation block  130 . The target rotation speeds of the left and right motors  41  ( 40 L and  40 R) are calculated based on the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle speed v, on the difference between the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) corresponding to the target vehicle angular velocity ω, on the target vehicle acceleration a or the target vehicle deceleration d, and on the target vehicle angular acceleration a or the target vehicle angular deceleration δ. 
     As described above, not only the target vehicle speed v and the target vehicle angular velocity ω depending on the inclination angle λ, but also the target vehicle acceleration a or the target vehicle deceleration d and the target vehicle angular acceleration a or the target vehicle angular deceleration δ set depending on the inclination angle λ are reflected, and the target rotation speeds of the left and right motors  41  ( 40 L and  40 R) are calculated. The left and right motor required torque calculation block  150  calculates the left and right motor required torques on the basis of the deviation between the actual rotation speeds of the left and right motors  41  ( 40 L and  40 R) and the target rotation speeds, thus executing current control for the left and right motors  41  ( 40 L and  40 R). 
     (Target Vehicle Deceleration Map) 
       FIG. 10  shows a target vehicle deceleration map that defines a relationship between the vehicle actual speed v and the target vehicle deceleration d for target vehicle deceleration calculation ( 112 ). Solid lines in the diagram indicate the target vehicle deceleration map in the case with the inclination angle λ=λ 0  (zero inclination). Broken lines indicate the target vehicle deceleration map in the case with the inclination angle λ=λm (set maximum inclination angle). 
     These target vehicle deceleration maps are stored as look-up tables in the ROM area of the control unit  10 . When the inclination angle λ is zero degrees or less than a predetermined threshold λ 1  (e.g., three degrees) that can be substantially assumed as flat land, the target vehicle deceleration map with the inclination angle λ=λ 0  is applied. When the inclination angle λ is equal to or greater than the set maximum inclination angle, the target vehicle deceleration map with the inclination angle λ=λm is applied. When the inclination angle λ is equal to or greater than the predetermined threshold λ 1  and is less than the set maximum inclination angle λm, calculation is performed using the expression 2 described above. 
     According to the target vehicle deceleration map shown in  FIG. 10 , when the vehicle actual speed v in the forward traveling direction is in the high speed region (e.g., 4 km/h or higher), the maximum target vehicle decelerations da and dm during traveling forward are designated. With respect to the target vehicle deceleration da (e.g., 5 km/h/s=1.39 m/s 2 ) in the case with the inclination angle λ=λ 0 , the target vehicle deceleration dm (e.g., 4 km/h/s=1.11 m/s 2 ) in the case with the inclination angle λ=λm has a small value. Thus, when the inclination angle λ is large, rapid deceleration is prevented. 
     On the other hand, when the vehicle actual speed v in the backward traveling direction is in the high speed region (e.g., −1 km/h), the maximum target vehicle deceleration db (e.g., 7 km/h/s=1.94 m/s 2 ) during traveling backward is designated. However, during backward traveling, the target vehicle deceleration d is not changed depending on the inclination angle λ. In the backward traveling direction, the absolute value of the traveling speed is suppressed to that of a low speed. Accordingly, even if the target vehicle deceleration is set similarly to that in the case of a flat road, the deceleration is not rapid, and secure stopping is prioritized. 
     Note that during traveling forward and during traveling backward, the target vehicle deceleration d decreases with decrease in the vehicle actual speed v. At a speed of zero and in the low speed region, the value becomes a lower limit value d 1  (e.g., 1 km/h/s=0.28 m/s 2 ). 
     (Target Vehicle Angular Deceleration Map) 
       FIG. 11  shows a target vehicle angular deceleration map that defines a relationship between the angular velocity ω and the target vehicle angular deceleration δ for target vehicle angular deceleration calculation ( 122 ). Solid lines in the diagram indicate the target vehicle angular deceleration map in the case with the inclination angle λ=λ 0  (zero inclination). Broken lines indicate the target vehicle angular deceleration map in the case with the inclination angle λ=λm (set maximum inclination angle). 
     According to the target vehicle angular deceleration map shown in  FIG. 11 , in comparison with the target vehicle angular deceleration δ 1  in the case with the inclination angle λ=λ 0  (e.g., 480 degrees/s 2 =8.38 rad/s 2 ), a large target vehicle angular deceleration δm (e.g., 1800 degrees/s 2 =31.4 rad/s 2 ) is designated in the case with the inclination angle λ=λm. Even when the inclination angle λ is large, the turning can be securely stopped against the moment of inertia. 
     (Rapid Stop Control in Riding Mode) 
     In each of the aforementioned embodiments, control during normal operation on the joystick  83  based on the basic target vehicle speed map ( FIG. 6 ) and target vehicle angular velocity map ( FIG. 7 ) has been described. In a state in which the joystick  83  is operated forward, and forward traveling or forward turning traveling is performed at a vehicle speed equal to or higher than a predetermined threshold val (e.g., 0.5 km/h), when the joystick  83  is subjected to a reverse operation backward, rapid stop control is executed irrespective of the left or right direction component. 
     That is, in the block diagram shown in  FIG. 5 , joystick inputs into the target vehicle speed calculation block  110  and the target vehicle angular velocity calculation block  120  are ignored. The target vehicle speed v and the target vehicle angular velocity ω are set to zero. Based on the vehicle actual speed and the inclination angle λ input into a vehicle rapid stopping deceleration calculation block  113 , the target vehicle rapid deceleration d is calculated. 
       FIG. 12  shows a target vehicle rapid deceleration map that defines a relationship between the vehicle actual speed v and the target vehicle rapid deceleration d for target vehicle rapid deceleration calculation ( 113 ). Solid lines in the diagram indicate the target vehicle rapid deceleration map in the case with the inclination angle λ=λ 0  (zero inclination). Broken lines indicate the target vehicle rapid deceleration map in the case with the inclination angle λ=λm (set maximum inclination angle). 
     As shown in  FIG. 12 , during rapid stop control, depending on the vehicle actual speed v at the start of rapid stop control, the target vehicle rapid deceleration is set from the maximum target vehicle rapid decelerations da′ and dm′, which are sufficiently greater than those during normal control ( FIG. 10 ), to the target vehicle rapid deceleration d 1 ′ at the vehicle speed threshold val in rapid stop control, in order to securely achieve braking and stopping in a short time as much as possible. 
     Here, with respect to the maximum target vehicle rapid deceleration da′ (e.g., 15 km/h/s=4.17 m/s 2 ) in the case with the inclination angle λ=λ 0 , the maximum target vehicle rapid deceleration dm′ (e.g., 7 km/h/s=1.94 m/s 2 ) in the case with the inclination angle λ=λm has a small value. 
     This is because in addition to the fact that on an inclined surface the vehicle actual speed at the start of rapid stop control subjected to lambda control is suppressed in the low speed region in comparison with that during flat ground travel, the load on the user becomes large on a downhill inclined surface due to rapid braking, and conversely, on a climbing inclined surface, a large braking force is not required in comparison with the case on the flat road. The target vehicle rapid deceleration d 1 ′ (e.g., 3 km/h/s=0.83 m/s 2 ) at the minimum vehicle speed val (e.g., 0.5 km/h) at which the rapid stop control is actuated is designated to have the same value. 
     As described above, according to the target vehicle rapid deceleration map, the rapid stopping deceleration control is executed. Regenerative braking by the left and right motor units  40  is executed. In a state in which the electric vehicle  1  has a predetermined low speed or lower, the left and right motor units  40  are locked by the respective electromagnetic brakes  42 , and the electric vehicle  1  is completely stopped. 
     When the joystick  83  is operated forward, or to the neutral position n during the rapid stop control (or when being returned by itself), or when a predetermined time period (e.g., four seconds) elapses after the vehicle is stopped by the rapid stop control, the rapid stop control is finished, and the control transitions to normal control on the basis of the operation position of the joystick  83  and the inclination angle λ at the time. 
     As described in detail above, the electric vehicle  1  according to the present invention changes the speed control and the acceleration/deceleration characteristics depending on the inclination angle λ when the inclination in the forward and backward direction (pitch angle P) and the inclination in the width direction (roll angle R) that affect the travel of the small electric vehicle are integrated, and obtains the acceleration/deceleration characteristics and turning characteristics optimized depending on the road inclination and the travel state only through an intuitive operation on the joystick  83  by control that changes the turning characteristics depending on the inclination angle λ and the vehicle actual speed. The characteristics are advantageous in improving simplification of the operation and the usability. Furthermore, the loads on the vehicle body system and motors are reduced, which is advantageous in reducing the weight of vehicle body and the manufacturing cost. 
     In particular, according to the target vehicle speed control ( 110 ) in consideration of the inclination angle λ, when the inclination angle λ is significant with respect to the flat road, reduction in target vehicle speed can reduce the load on the user due to the road inclination and the travel of the vehicle, and the load on the motors. 
     Likewise, according to the target vehicle angular velocity control ( 120 ) in consideration of the inclination angle λ, when the inclination angle λ is significant with respect to the flat road, reduction in target vehicle angular velocity can reduce the load on the user due to the road inclination and the turning behavior of the vehicle, and the load on the motors. 
     In addition, according to the target vehicle acceleration control ( 111 ) in consideration of the inclination angle λ, when the inclination angle λ is significant with respect to a flat road, increase in target vehicle acceleration mainly in the low speed region compensates for the delay of rising of the acceleration/deceleration control due to reduction in target vehicle speed, and operability similar to that on a flat road is achieved. 
     Likewise, according to the target vehicle angular acceleration control ( 121 ) in consideration of the inclination angle λ, when the inclination angle λ is significant with respect to a flat road, increase in target vehicle angular acceleration compensates for the delay of rising of the turning control due to reduction in target vehicle angular velocity, and turning operability similar to that on a flat road is achieved. 
     Furthermore, according to the target vehicle deceleration control ( 112 ) in consideration of the inclination angle λ, when the inclination angle λ is significant with respect to a flat road, reduction in target vehicle deceleration can reduce the load on the user due to the road inclination and the deceleration behavior of the vehicle. 
     According to the target vehicle angular deceleration control ( 122 ) in consideration of the inclination angle λ, when the inclination angle λ is significant with respect to the flat road, increase in target vehicle angular deceleration can securely and rapidly stop turning against the moment of inertia even on an inclined surface, and obtain operability similar to that on a flat road. 
     The embodiments of the present invention have been described above. However, the present invention is not limited to the embodiments. Based on the technical concept of the present invention, various modifications and changes can further be made. 
     For example, in the embodiments described above, the case in which the electric vehicle  1  has the rollator mode has been described. However, the present invention can be implemented as a small electric vehicle or an electric wheelchair that has no rollator mode. 
     In the embodiments described above, the case of including the omni wheels as driven wheels  5  has been described. Alternatively, caster type free wheels may be included.