Journal of Electrical Engineering and Technology

The Korean Institute of Electrical Engineers (대한전기학회)
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Design and Evaluation of the Unmanned Technology Research Center Exoskeleton Implementing the Precedence Walking Assistance Mechanism

  • Cha, Dowan (Dept. of Mechanical Engineering, KAIST) ;
  • Oh, Sung Nam (Dept. of Electrical Engineering, Myong Ji University) ;
  • Lee, Hee Hwan (Dept. of Electrical Engineering, Myong Ji University) ;
  • Kim, Kyung-Soo (Dept. of Mechanical Engineering, KAIST) ;
  • Kim, Kab Il (Dept. of Electrical Engineering, Myong Ji University) ;
  • Kim, Soohyun (Dept. of Mechanical Engineering, KAIST)
  • Received : 2014.05.20
  • Accepted : 2015.06.24
  • Published : 2015.11.01
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Abstract

Assistance of the operator’s walking ability while carrying a load is a challenging area in lower limb exoskeletons. We implement an exoskeleton called the Unmanned Technology Research Center Exoskeleton (UTRCEXO), which enables the operator to walk with a load more comfortably. The UTRCEXO makes use of two types of DC motor to assist the hip and knee joints. The UTRCEXO detects the operator’s walking intention including step initiation with insole-type FSRs faster without using any bio-signals and precedes the operator’s step with a reference torque. It not only reduces interaction forces between the operator and the UTRCEXO, but also allows the operator to walk with a load more comfortably. In this paper, we present the UTRCEXO implementing the walking assistance mechanism with interaction force reduction during walking.

Keywords

1. Introduction

A lower limb exoskeleton is an active mechanical device that assists the operator in walking more comfortably with loads, or enables persons suffering from paraplegia to walk [1-2]. It can be described as a walking assistive exoskeleton and an orthotic exoskeleton, respectively. There are six important technologies for the lower limb exoskeleton: actuator technology, mechanism technology, control technology, sensor technology, detection of human walking intention technology, and human-robot interface technology [3-4]. In particular, the detection of human walking intention has been an important challenge in developing a lower limb exoskeleton. Walking assistive exoskeletons attempt to detect human walking intention including step initiation as soon as possible because a faster detection of step initiation initiates first step of the exoskeleton faster, but also because it allows the operator to walk more comfortably [5-8]. There are two types of approach to detect walking intention including step initiation in the walking assistive exoskeleton: a precedence walking assistance mechanism and a shadow walking assistance mechanism [9].

The precedence walking assistance mechanism detects the walking intention including step initiation of the operator prior to visible movements of the operator by using bio-signals. The robot suit Hybrid Assistive Limb (HAL) makes use of such bio-electrical signals, including ElectroMyoGraphy (EMG), and Floor Reaction Force (FRF), to detect the walking intention including step initiation of the operator before the corresponding visible movements occur [10-11]. As a result, the HAL can not only initiate its step before the step of the operator, but also precede the steps of the operator more comfortably. However, the issues encountered with bio-signals, such as low reliability, and long calibration times for each person have limited further development of the precedence walking assistance mechanism. The HAL has DC motors at each hip and knee joint with a harmonic drive placed directly on the joints. Additionally, the HAL utilizes a number of sensors to operate the suit, including potentiometers, FRF sensors, a gyroscope, and accelerometer [12].

In contrast, the shadow walking assistance mechanism detects the walking intention including step initiation of the operator after the visible movements of the operator occur, such as the heel-off event or the toe-off event. The RoboKnee detects the walking intention based on both the center of pressure and the heel-off event, when the heel is lifted just before the front end of the foot leaves the ground. It does so by using two load cells installed in stiff-bottom bicycle shoes. The RoboKnee has a linear Series Elastic Actuator (SEA) connected between the knee and hip. The Roboknee amplifies power at the knee to assist the walking ability of the operator [13-14]. The Berkeley Lower Extremity Exoskeleton (BLEEX) detects the walking intention including step initiation of the operator with toeoff events, when the toe leaves the ground, by using a foot switch installed in their shoes [15-16]. The BLEEX makes use of a number of sensors to operate itself, including encoders, linear accelerometers, force sensors, and an inclinometer [17].

These approaches are reliable because they detect walking intention, including step initiation, after visible movements related to walking have occurred. However, these approaches have stronger interaction forces between the operator and the walking assistive exoskeleton, requiring faster control schemes based on the good dynamics of the system. They also require more sensors in order to operate.

Meanwhile, orthotic exoskeletons must attempt to detect the walking intention of the operator including step initiation more accurately, because they are intended for paraplegic users who cannot provide any motion of the legs and have difficulty with stability [18-19]. The ReWalk detects walking intention of the operator including step initiation by using torso angles and buttons installed in forearm crutches [20]. The eLegs detects walking intention of the operator including step initiation by using arm motion with forearm crutches [21].

In this paper, we describe a walking assistive exoskeleton called the Unmanned Technology Research Center Exoskeleton (UTRCEXO). The UTRCEXO implements the precedence walking assistance mechanism for walking including step initiation without using bio-signals. We analyzed the human gait from a quiet standing position to continuous walking using force plates and motion capture devices. We implemented the precedence walking assistance mechanism in the UTRCEXO with the peak time approach and then evaluated its performance.

We provide details and specifications of the UTRCEXO in Section 2. We then discuss the method how to detect walking intention of the operator in Section 3. Next, we discuss the evaluation of the UTRCEXO in Section 4. Finally, in Section 5, we discuss the results and future work.

 

2. Design

Fig. 1 shows an image of the UTRCEXO. The UTRCEXO has two actuated degrees of freedom in each leg for hip flexion/extension and knee flexion/extension. Additionally, the UTRCEXO has two actuated degrees of freedom in each arm for shoulder flexion/extension and elbow flexion/extension. In total, the UTRCEXO has 8 actuators. The UTRCEXO provides hip and shoulder abduction/adduction without any actuator. Meanwhile, the UTRCEXO has a modular design with variants that include a lower limb exoskeleton without arms and a whole body exoskeleton with arms. The torso section of the UTRCEXO consists of a rigid link to match with the spine of the operator and a plate on which to hang a load. The UTRCEXO attaches to the operator at the waist, each thigh, each shank, and each foot by using straps.

Fig. 1.Image of the UTRCXO (◎: 90 W DC motor, ◎: 150 W DC motor, ◎: F/T sensor, ◎: Insole-type FSRs)

Additionally, there are two shoulder straps with a bag for the load. Table 1 lists the specification of the UTRCEXO in detail, and Fig. 2 shows the system of the UTRCEXO in detail. The main components of the UTRCEXO are introduced in the following subsections.

Table 1.Specification of the UTRCEXO

Fig. 2.System of the UTRCXO.

2.1 Actuator

The UTRCEXO has 8 actuators. Fig. 3 shows the actuator of the UTRCEXO. The actuator was developed as a whole body type actuator, including a reduction gear, a motor, a sensor, and a controller. The actuators are capable of performing both position control and torque control using position sensors and current sensors. The UTRCEXO has two types of DC motor: 90 W DC motors at each arm and 150 W DC motors at each leg, with a 233:1 harmonic drive gear reduction. The actuators have an absolute magnetic rotary encoder (MRE) to measure joint range of motion (ROM) of the UTRCEXO from reference position. The resolution of the MRE is 360 degrees/12 bits with 0.09 degrees of error. The motion controller makes use of a micro controller unit (STM 32F 103) based on a 32 bit ARM M3 core, and its power consumption is 300 W (24 V, 15 A). The motion controller utilizes an RS 485 communication line with a 3 Mbps and the sampling rate is 50 Hz. A current sensor provides further feedback for the control system. The resolution of the current sensor is 12 bits. The current provides a measurement of torque, which is driven by the controller to a reference. The reference torque for each joint was calculated from an inverse dynamics model based on gait pattern analysis of subjects measured by force plates [22-23].

Fig. 3.Whole body type actuator. It consists of a reduction gear, a motor, a sensor, and a controller.

2.2 Sensors

We developed insole-type force sensing resistors (FSRs) to detect walking intention including step initiation of the operator [24]. The UTRCEXO has only a single two-channel FSR (FlexiForce 251bs) for each foot, with a sensor on the heel and the toe, and a MCU. Measured data are filtered using an 8 channel Op-amp filter with a cutoff frequency of 1 kHz. The force sensitivity range is from 0.1 N to 10 N, and the pressure sensitivity range is from 1.5 psi to 150 psi. The resolution of the insole-type FSRs is 12 bits. The sampling rate of the insole-type FSRs is 10 kHz. Additionally, we developed a 3 axis (X-Y-Z) F/T sensor, which is shown in Fig. 4. We utilized a binocular tunnel for the flexibility of a strain gauge. F/T sensors were installed in the footplates of the UTRCEXO and measure the interaction forces between the operator and the UTRCEXO. The range of force is from 100 g to 120 kg and the resolution of the F/T sensor is 12 bit. The sampling rate of the F/T sensor is 10 kHz and the cutoff frequency is 100 Hz.

Fig. 4.Image of the F/T sensor.

2.3 Control scheme

The UTRCEXO detects step initiation of the operator using the peak time approach from the insole-type FSRs. The peak time approach detects step initiation of the operator with two particular ground reaction force events before visible movements occur, such as heel-off, knee flexion, and toe-off movement [25]. Once the UTRCEXO detects step initiation, the human intention detector of the UTRCEXO transmits each required joint torque as a reference torque to the motion controller using a RS485 communication line. These reference torques were calculated from an inverse dynamics model based on the gait pattern analysis of subjects with force plates [22]. The UTRCEXO starts to walk prior to the walking of the operator. During continuous walking, the UTRCEXO makes a gain selection with the walking intention of the operator based on a previous step velocity. With the gain selection, the UTRCEXO is still being controlled according to the walking intention of the operator. Additionally, the UTRCEXO detects step termination with the interaction force between the operator and the UTRCEXO, as measured by the F/T sensors installed in each foot-plate. Fig. 5 shows the flowchart of the control scheme. The sampling rate of the controller is 50 Hz.

Fig. 5.Flowchart of the control scheme.

 

3. Detection of Walking Intention

We developed an algorithm to detect the walking intention of the operator. We modeled the unit walking behaviors of the UTRCEXO as states of the UTRCEXO from Moore Automation for Robot Behavior (MARB) [26-27]. A transition function determined step initiation and proper walking behaviors of the operator. MARB A is defined as:

For the set of conditions C, and the set of operations Op, the elements are defined as:

Q = Op×(C)* corresponds to the set of states

For q∈Q : q = (id, op, (c1, id1),…,(c|q|, id|q|)), c :: = true | false | (ck o cj) | f(v) ∈ C

where

- id is the state’s unique identifier - Op is the set of operation - C is the set of conditions of the transition - the (c|q|,id|q|) encode the outgoing transitions - |q| denotes the number of conditions of state q - c is defined as condition - ois o∈ {AND,OR} - ck,cj are conditions - f(v) is the function to judge that the inputs

For any element x of A, the notation xq denotes that x belongs to state q.

- The input alphabet Σ = V =(B)|H| - The output alphabet Ω = Op - The transition function δ: Q×V→Q

for q∈Q, v ∈ V.

- The output function λ : Q → Op : λ(q) = opq =(cmdq, parq), for q∈Q. - The initial state q0∈Q.

In the UTRCEXO, the output range of the 4 FSR sensors and the 2 F/T sensors is B = {0,….,255} and H = {h1,.., h6}. v ={v1,.., v6}∈V = B6 refers to the acquired data from the FSRs and F/T sensors. If the condition is true, the transition occurs to operate the UTRCEXO with the output function. We previously analyzed human gait patterns from step initiation to continuous walking, and proposed a new approach called the peak time approach to detect step initiation [25]. For the UTRCEXO, we defined the states from step initiation to step termination with the acquired data from FSRs and F/T sensors. It has a total of 6 states as follows:

- Equipment/Standing - Step initiation - First step - Continuous walking - Step termination - Walking completion

Walking intention of the operator is detected with these states and the transition of these states. The UTRCEXO operates with an output function according to the state from the transition function. There are 3 commands including step initiation, continuous walking and step termination. Additionally, there are 2 parameters including right and left. The state of the UTRCEXO changes with the function described in (2). The transition function determines the next state from input alphabet and conditions. The input alphabets are values from FSRs and F/T sensors. The UTRCEXO detects step initiation using two particular events from FSRs with the peak time approach, and then walks continuously according to the intention of the operator. The UTRCEXO detects the intention of the operator for continuous walking and step termination with values from F/T sensors. There are thresholds to determine the intention of the operator based on human gait analysis and trial/error.

 

4. Evaluation

The operators during the evaluation did not have postural problems and gave informed consent, approved by the Institutional Review Board of KAIST prior to participating in the evaluation. The operators’ height (mean value) was 1.76 m and weight (mean value) was 73 kg. The operators wore the UTRCEXO with insole-type FSRs installed in his shoes. They stood with both feet and, upon the instruction to walk, tried to step with their right foot first with their preferred step velocity. Then, they terminated their step when they wanted in limited space. Fig. 6 shows the sequence of the UTRCEXO implementing the precedence walking assistance mechanism. The step velocity of the UTRCEXO in this evaluation was 3.9 km/h. There was a 10 kg payload hung on the back plate. The UTRCEXO walked, including step initiation prior to the walking of the operator according to the intention of the operator.

Fig. 6.Sequence of the UTRCEXO implementing the precedence walking assistance mechanism

Fig. 7 and Fig. 8 show the joint torques for the hip and knee transmitted to the motion controller. As was mentioned in Section II, these joint torques were calculated from an inverse dynamics model based on human gait analysis. After step initiation, the UTRCEXO walked continuously with transmitted joint torques from 0 % to 100 % in the gait cycle during continuous walking. The UTRCEXO terminated its step according to the step termination intention of the operator using the same detection algorithm of walking intention. Fig. 9 and Fig. 10 show joint ROMs of the UTRCEXO for hip and knee. Joint ROMs of the UTRCEXO were similar to the human gait pattern analyzed in the previous study [25]. In that previous study, the joint ROMs were 0 to 60 degrees for the knee flexion and extension and 5 to 40 degrees for the hip flexion and extension. Table 2 shows a comparison of the ROM for each joint between the UTRCEXO and the human gait pattern analysis. Fig. 11 shows a comparison of the interaction forces between the UTRCEXO implementing the precedence walking assistance mechanism and the transparent UTRCEXO for the swing phase. In the transparent UTRCEXO, the operator equipped with the UTRCEXO walked, including step initiation, without any transmitted torques. In Fig. 11, the interaction forces indicate the pull force of the operator during the swing phase. The interaction forces between the transparent UTRCEXO and the operator were 0 to 96 N, while the interaction forces between the UTRCEXO implementing the precedence walking assistance mechanism and the operator were 0 to 49 N in the swing phase. This clearly indicates that the UTRCEXO implementing the precedence walking assistance mechanism reduces the interaction force, which means that the operator can walk more comfortably even with a load.

Fig. 7.Joint torques of the UTRCEXO for right foot

Fig. 8.Joint torques of the UTRCEXO for left foot

Fig. 9.Joint ROM (right foot) of the UTRCEXO

Fig. 10.Joint ROM (left foot) of the UTRCEXO

Table 2.Comparison of ROM between the UTRCEXO and the human gait pattern

Fig. 11.Comparison result of the interaction forces

 

5. Discussion

In this paper, we presented the walking assistive exoskeleton called the UTRCEXO, which implements the precedence walking assistance mechanism using bio-signals. We evaluated the UTRCEXO and demonstrated that it is currently capable of providing a reduction of interaction forces during the swing phase with a load.

The UTRCEXO detects the walking intention of the operator including step initiation using by analyzing the feedback from insole-type FSRs and F/T sensors, using an algorithm we developed based on MARB. We also developed a whole-body-type actuator for the UTRCEXO’s joints, including a reduction gear, a motor, a sensor, and a controller. The UTRCEXO not only detects step initiation of the operator with the peak time approach using the insole-type FSRs prior to movement, but also walks continuously with reference joint torques. Additionally, by implementing the precedence walking assistance mechanism, the UTRCEXO can reduce the interaction forces during the swing phase, and also allow the operator to easily walk with a 10 kg load.

However, we implemented the precedence walking assistance mechanism in the UTRCEXO with reference joint torques calculated from an inverse dynamics model. It does not take the operator’s desired step velocity into account. Additionally, even though there was a reduction of the interaction forces between the UTRCEXO and the operator, further reduction would be desirable.

As a result, future research with the UTRCEXO will focus on three areas. First, we will work to incorporate the intention of the operator with regards to step velocity into the precedence walking assistance mechanism during continuous walking. Second, we will attempt to further reduce the interaction forces incurred during the swing phase. Third, we will measure muscle activity during walking using EMG sensors to quantifiably evaluate how comfortable the UTRCEXO operator is when walking with a load.

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