Online robotics technology course design by balancing workload and affect

3.1Course content

A fifteen-week lesson plan is given in Table 2, showing synchronization between projects and lecture topics. Corresponding course learning outcomes are also listed below.

Upon completion of the course, students are expected to be able to:

3.2Teaching remotely

The following describes a set of online teaching practices that replicate traditional face-to-face teaching as much as possible, simply virtually.

3.3New teaching activities

Two newly-developed teaching activities are described below, including frequent low-stakes online quizzes (Little-Wiles & Naimi, 2011; Eschenbach & Cashman, 2004; Yadav et al., 2011; Prince et al., 2020) and Blackboard online tests of randomly-chosen questions (Khan et al., 2021). The routine online quizzes helped to maintain students’ engagement in classes. The online test of random questions can serve as an online-appropriate assessment tool replacing traditional ways of paper-based methods (Khan et al., 2021).

4.1Path planning of a mobile robot using homemade simulator

The first project is to expose students to several important topics pertaining to autonomous mobile robots, including path planning, navigation, sensor detection, and basic motion control. Suppose a robot works in a known world with knowledge of locations of some fixed obstacles. We want the robot to go from one specified position (the initial position) to another specified position (the goal position), without collisions with any of these obstacles. Simultaneously, we would like the robot to build a map of its environment using some range sensors (for example, sonar sensors). The three figures on the top of Fig. 3 show the experimental setup at school using physical robots. A simulated version of this project was achieved via a homemade virtual environment, as shown at the bottom of Fig. 3.

Fig. 3

Path planning of an autonomous mobile robot: physical vs. simulation.

The physical project usually includes the following steps: 1) hardware assembly and software installation; 2) basic motion control, including translation (commanding the robot to go straight a specified distance) and rotation (commanding the robot to rotate a specified angle); 3) waypoint navigation (asking the robot to navigate through a given list of waypoints); 4) map building using sonar sensor (detect objects as the robot travels around); and 5) path planning (finding an obstacle-free path for the robot to go from a specified location to the goal location).

The simulation project includes 1) creation of a virtual environment; 2) detection of objects using range sensors; 3) clustering and recognition of clustered points as objects denoted by polygons; 4) waypoint navigation; and 5) path planning. Except for steps pertaining to controlling the physical robot, the simulation project includes all the key steps as the physical project. It also includes clustering and simple pattern recognition that were not addressed in the physical project.

4.2Trajectory generation of a robotic arm using MATLAB robotics toolbox

The second project is to expose students to several key components when controlling a robotic arm, including modelling, forward kinematics, inverse kinematics, and trajectory generation. Specifically, the task is to control a robotic arm’s end-effector to go through a given list of “via-points” in the 3D space. For in-person teaching, the VEX robotic arm (Fig. 4(a) and (b)) was analysed and used, which has a simple arm installed on its autonomous base. Under e-learning, the MATLAB Robotics Toolbox by Peter Corke (Corke, n.d.) was used to construct simulated robotic arms. Figure 4(c) and (d) show trajectory generation of a 4-DOF SCARA robot and a 6-DOF PUMA560 robot, respectively.

Fig. 4

Trajectory generation of Robotic arms: using physical robot (Ma & Ma, 2019) vs. simulated robot.

When using the physical VEX robot, students were guided through 1) modelling of the robot (i.e., measuring the length of links, angles, assigning coordinate frames); 2) obtaining the forward kinematics; 3) obtaining the inverse kinematics; 4) control of the robotic arm; and 5) trajectory generation that commands its end-effector to follow a given list of 3D “via-points”.

For the simulation project, students performed 1) construction of simulated robots; 2) obtaining forward kinematics; 3) derivation or implementation of the inverse kinematics; 4) implementation of trajectory generation in the 3D space; and 5) trajectory generation in the joint space. It can be seen that the key steps of forward and inverse kinematics and trajectory generation are performed in both projects.

4.3Vision-based control of autonomous robot using MATLAB-ROS

The third project is to introduce students to more advanced robotic control tasks. This has been a mission for this course since fall 2018. Simple vision-based control, i.e., visual servoing to a static object, was added as the third project. The control objective is to command a vision-enhanced VEX robot (Ma & Alborati, 2018; Ma et al., 2019) to face towards a visual landmark at a certain distance away. Figures on the top of Fig. 6 demonstrate the behaviour of the robot, together with the images captured by its onboard camera. The robot first orients itself towards the target and then moves to it. Correspondingly, the target on the image plane moves closer to the center of the image and then appears bigger.

For e-learning, we need a simulation platform that allows students to explore robotic applications of similar complexity. We resort to the Robot Operating System (ROS, https://www.ros.org/). Adoption of ROS in undergraduate curriculum is still limited, due to its demanding requirements of C++/Python programming skills and familiarity with Linux (Lehman & Hayder, 2015; Wilkerson et al., 2017; Khasim, 2017; Canas et al., 2020). MathWorks’ release of its ROS Toolbox allows much easier interaction with ROS-enabled physical robots or simulators (such as Gazebo). Students can also use many other MATLAB Toolboxes (such as Image Processing and Navigation Toolboxes) for fast data processing and algorithm prototyping (Avanzato, 2020; Avanzato & Wilcox, 2020).

ROS was introduced into the Robotics Technology course under the MATLAB-ROS-Gazebo package, which involves MATLAB, the ROS middleware, and the 3D Gazebo simulator. The whole package requires a fair amount of downloading, installation, and introduction of the entire system, including:

Fig. 5

MATLAB-ROS- Gazebo simulation environment.

Due to the complexity of the ROS project, sample programs were provided to the students. Students were asked to make extensions on top of these sample programs to achieve a control task that involves a) collection of sensor data, b) data processing, and c) control of the robot’s motion. With the preparation and introduction of the MATLAB-ROS package, students were able to perform visual servoing to a static object (i.e., the blue cube as shown in Fig. 6(b)), as a variation of the physical project shown in Fig. 6(a). Visual servoing is to control the robot’s orientation and/or position with respect to a visual landmark. An image-based visual servoing method was implemented, which adjusts the robot’s orientation until the target’s center is close to the image center horizontally. The MATLAB-ROS platform, once installed on the students’ own computers, allows them to continue exploring robotics-related tasks outside of the classroom, thus promoting activities at the level of undergraduate research.

Fig. 6

Vision-based control: using physical vs. simulated Robots.

In summary, this section presents the three simulation projects that were designed for e-learning, covering fundamental subjects in autonomous mobile robots, robotic manipulators, and advanced robotic control tasks. Since robotic software systems are complex, it is advisable to expose students gradually to such complexity (Canas et al., 2020). Thus, these simulation projects were designed with increasing complexity. Project 1 aims at preparing students to obtain basic understanding and programming experience. Students will then acquire more solid programming skills in Project 2. Project 3 eventually exposes students to real-world software design and algorithm implementation. Step by step, students will acquire the knowledge, skills, and experience of designing and implementing algorithms for robotic applications.

4.4Conduction of projects and deliverables

In fall 2020, the course was taught completely online. Students were allowed to work either individually or with another member. The maximum number of students allowed in each group is two. Out of 21 students, seven students chose to work individually. The rest worked in groups of two.

Since project-based learning was adopted for both physical and simulation projects, each student or group was allowed to take a slightly different pace. We aim at creating a friendly and encouraging learning environment where students will always be welcome. They will not be punished for just being a little behind. The majority of the students were able to proceed with the suggested pace, with few students faster or slower. Students also helped each other to identify issues and debug. When pre-recorded lessons are available, students could also review these recordings. Students who did not finish during the lab sessions would usually spend more time on their own (since they have access to the software all the time). They also came to the virtual office hours when they still had questions unanswered.

The purpose of Project 1 is to prepare students with basic programming skills for algorithm implementation. The instructor provided as much help as needed. Starting from Project 2, the instructor gradually became hands-off. For Project 3, where students were asked to define their own tasks, the instructor only provided guidance at the idea-level, e.g., discussing potential challenges and possibility of completing tasks in time. There was almost no coding help for Project 3. Under this teaching style, almost all students completed Projects 1 and 2. For Project 3, most students provided a solution to their self-defined tasks, though the difficulty of each task varies.

Since the simulation projects are designed as companions of those physical projects, students’ deliverables for simulation projects are the same as those for physical projects. That is, the deliverables are mainly determined by the nature of each project, instead of the teaching format. For Projects 1 and 2, the instructor checked each step during lab sessions; upon completion, students were asked to write a report documenting major steps. For Project 3, students’ deliverables are group presentations and live classroom demonstrations.

5.1Lecture-related workloads: online vs. in-person

For lecture-related workloads, Table 6 summarises our course redesign process, by listing each workload component, the identified conflict between in-person and online teaching (i.e., the need for redesign), the design solutions (i.e., actions we took), and our self-evaluation of the similarly to their in-person counterparts. The similarity is judged based on workload complexity, ability to reinforce intended concepts, and generated stress for students.

Some workloads (such as course content, learning objectives, lecture notes, and homework assignments) were used previously in the in-person teaching mode. These materials are carried on to the online teaching without any change. Under e-learning, the exams are heavier than before due to the addition of an online test. Moreover, a set of online quizzes are added in lectures to promote classroom participation, as well as preparing students to take tests online. In Fig. 7, workloads in the overlapped area represent the same workloads shared by both. Others are either conducted differently (exams) or added new (online quizzes).

We closely monitored students’ reactions about these newly-added workloads, making sure they actually served their good intention without overwhelming the students. The online quizzes are intended to be low-stakes, without giving students much pressure. In most cases, they serve as classwork rather than assessment tools. Should students have questions, the instructor will explain it to the whole class. Regarding online tests, after the first exam (Exam #1), we asked students if they liked the way Exam #1 was structured (i.e., consisting of an online test plus an at-home test). Students had no complaints about it. One student said he actually liked how Exam #1 was structured and conducted. Both the online quizzes and online tests were also used in two other courses (a junior-level electric circuit course and a senior-level control course) since e-learning started in spring 2020. So far, we have not received any complaints about them at all. We thus believe these added workloads do not cause extra stress for students.

Fig. 7

Lecture-related workloads conducted in-person vs. online.

In summary, we think our course redesign yielded similar workloads as those performed in-person, without causing extra stress for students.

5.2Project-related workloads: online vs. in-person

The course redesign process for project-related workloads is summarised in Table 7.

Technically, software-related workloads in terms of software design and algorithm implementation can be adequately performed using simulations. Through significant course redesign, the achieved similarity to the in-person version can be very high. The only conflict hard to resolve is regarding those truly hardware-concentrated activities, including, for example, hardware assembly, wiring of sensors and actuators, and communication between two hardware devices. Though these topics can be demonstrated using simulated robots, we feel they cannot be adequately addressed via simulations.

To achieve similar overall project-related workloads, several new topics on algorithm implementation were added, including clustering and data processing, trajectory generation of robotic arms in joint space, obstacle avoidance, and control of the PR2 robotic arm on MATLAB-ROS. These topics were unable to be covered when using physical robots in the past, since handling the hardware took time. We are able to address them now under e-learning.

As illustrated in Fig. 8, our course redesign for project-related workloads obtained similar overall workloads as before, by keeping some workloads approximately the same, some performed slightly differently, some demonstrated as much as possible, and others added new.

Fig. 8

Project-related workloads conducted in-person vs. online.

In the next, we describe the arrangements we made, which ensured the execution of the simulation projects without causing too much stress on students.

Regarding the software, MATLAB is easy to install. Before the pandemic, our institution already provided a licence to students to install MATLAB on their own computers. This licence is updated annually. So, some students had MATLAB already. Moreover, MATLAB is commonly used in the STEM fields. Some students have already used it before in other courses (such as maths, circuit analysis, and feedback and control courses). Before classes began, we sent emails to students and posted announcements on Blackboard, asking students to install MATLAB in advance. During the first couple of weeks, should students ask questions about how to install MATLAB, we would spend time guiding them to complete the installation process (which is pretty standard). Other students who had similar issues can follow along. We also listed all the Toolboxes to be used for our projects, so that students can simply install them instead of all the Toolboxes to save computer space.

To make sure that students have the proper knowledge and programming skills using MATLAB, the first two lab sessions were used to cover the fundamentals of MATLAB programming and debugging, assuming basically zero prior background. These labs helped students to get familiar with the MATLAB programming environment. At the beginning of each project, students were required to share their computer screen. The instructor took a record of who had already shared. These records were inputted to Blackboard as part of classroom participation, reminding students such activities were to be completed. These mandatory screen sharing pushed the students to have the proper setup for each simulation project.

Once getting started, the instructor usually allocated 30 minutes in each lab session for students to share their computer screens and get assistance. Students were also encouraged to help each other to debug and fix errors in the codes. We made sure that a friendly and encouraging online learning environment was created, so that students were welcome to ask any questions. We also allowed students to choose to work either individually or with another member to get support.

All these arrangements help to ensure that the project-related workloads are reasonable and manageable, without over-stressing the students.

6.1Student exam grades

When the course was taught in-person from spring 2017 to fall 2019, the midterm exam and the final exam were used to evaluate course learning outcomes 1∼4 and 5∼9 (Sec. 3.1), respectively. The course learning outcomes (1∼4) are regarding students’ abilities on basic motion control of an autonomous mobile robot, while outcomes (5∼9) are on students’ abilities of conducting analyses and control of a robotic manipulator. These two exams were in-class, closed-book, closed-note, closed-computer, providing a summative assessment of students’ learning and knowledge (Guilford & Helmke, 2017).

Spring 2020 was the first time the course was taught online. The midterm exam was right on spot when transitioning from in-person to online. It was assigned as a take-home exam. All students got a score higher than 70 (out of 100). But we decided not to use these as assessment results since the exam was not performed during the class period. With an assessment in mind for online teaching, we prefer activities done in-class, which has the same time restriction as pre-pandemic in-person exams. To obtain an online-appropriate assessment, we resort to the Blackboard online test of randomly chosen questions.

In spring 2020, we did one online test as part of the final exam. In fall 2020, we did two online tests. Assessment using the online tests (in yellow), together with those collected in six past in-person offerings using in-class exams (blue), are shown in Fig. 9. Notice that assessment in Spring 2020 for Course Learning Outcomes (1∼4) was treated as “unperformed” and is left blank in Fig. 9(a). Setting 70% as the target for being “Proficient and/or Satisfactory”, course learning outcomes (1∼9) were successfully obtained under the considered semesters under online teaching.

Fig. 9

Assessment of course learning outcomes (1∼9): in-person vs. online.

To observe the effect of teaching modes (in-person vs. online) on students’ learning performance, students’ exam grades crossing eight semesters were analysed using One-Way analysis of variance (ANOVA) via MATLAB’s Statistics and Machine Learning Toolbox, particularly, the anova1() function. The One-Way ANOVA provides results to determine any statistically significant differences between the means of two or more independent samples, i.e., whether different groups of an independent variable have different effects on the response variable (Kumpass-Lenk et al., 2018; Boysen, 2015; Saleheen et al., 2015; Khan et al., 2018). In this analysis, the independent variable is the teaching mode having two levels: in-person and online. The response variable is students’ learning achievement reflected by their Exam#1 and Exam#2 grades.

Students’ Exam #1 grades (21 students in fall 2020) and Exam #2 grades (22 students in spring 2020 and 21 students in fall 2020) are compared with those obtained in six past in-person semesters (126 students in total). Table 8 shows the ANOVA results and their corresponding box plots. In both plots, Group #1 denotes the group of in-person students, and Group #2 is for the online students. Comparison between both groups of students using Exam#1 [Fig. (a)] shows a p-value of 0.0522. When using Exam#2, the ANOVA analysis yielded a p-value of 0.4878 [Fig. (b)]. Since both p-values are greater than 0.05, the results of the ANOVA tests indicate there is no sufficient evidence that these two groups of students under comparison perform differently. These results demonstrate the effectiveness of our course design and teaching practices in overcoming the challenges/barriers presented by online teaching.

Table 8

ANOVA test results of students’ exam grades

In terms of difficulty and challenge, both Exam #1 and Exam #2 of each semester were designed to be comparable (approximately the same). The online tests decomposed a multi-step question into smaller steps, making them suitable to be tested online using multiple choice, fill-in-blank, and true/false questions.

To see if there were any initial differences in students’ prior knowledge in mathematics (which is very important for this course), students’ grades of two homework assignments (one in complex numbers and the other in linear algebra) were used. The homework on complex numbers (say hw#1) was assigned at the beginning of this robotic course. The homework on linear algebra (say hw#2) was assigned around week 6 in each semester. In this study, scores of the spring 2020 students were counted towards the in-person group, since their prior knowledge was obtained before online teaching started. Besides, both assignments were collected before the pandemic. For hw#1, the mean and standard deviation for the in-person and online students were 7.91 (SD = 2.97) and 6.63 (SD = 3.62), respectively. A further ANOVA test yielded a result of F (1, 167) =3.25, p = 0.0734. As for hw#2, the mean and standard deviation for the in-person and online students were 6.91 (SD = 3.50) and 6.96 (SD = 3.65). A further ANOVA test yielded a result of F (1, 167) =0.0035, p = 0.953. We feel it is safe to say that students in both in-person and online teaching demonstrated a similar level of readiness for the robotic course before entering the course.

6.2Student creative thinking capabilities

Creative thinking is an important skill needed for the modern workplace (Bielefeldt & Morse, 2019). Since robotics inherently demands creativity and requires investigation among several different methods to eventually come up with a solution (Eteokleous et al., 2020; Alimisis, 2013; Kuo et al., 2021), we have been assessing students’ creative thinking capabilities sing fall 2028 using Project 3. After preparing students with fundamental knowledge and skills using lectures and the first two projects, the third project is dedicated towards solving possibly open-ended questions, thus providing an opportunity for students to practice their creative thinking skills. The nature of being open-ended implies that multiple solutions might exist for a given problem. Students thus need to explore among different methods to find the most appropriate approach, or to come up with their own/new way. Further, our teaching methodology of providing only supervision, instead of detailed instructions, pushes students to take the risk factor into consideration. Five out of six performance criteria from the Creative Thinking Value Rubric were assessed (Ma et al., 2021), as given in Table 9. The criterion of “Connecting, Synthesising, and Transforming” was not utilized since it generally corresponds to the highest level of creative thinking and may not be adequately evaluated in this course that focuses on robotics subjects only. A numerical value was assigned by the instructor for each students’ performance under each criterion on a scale of 1 to 4, with Score-1 corresponding to “Unsatisfactory”, Score-2 for “Developing”, Score-3 for “Satisfactory”, and Score-4 for “Proficient”. The assessment results in three past in-person semesters and one online semester (fall 2020) are shown in Fig. 10.

Fig. 10

Assessment of students’ creative thinking using project 3: In-person Vs. online.

Again using 70% as the target for being “Proficient and/or Satisfactory” (i.e., score of 3 and/or 4), it can be seen that students’ performance regarding the five indicators either stabilized around/above the target of 70% after some initial overshoot, or steadily improved/increased to reach and go beyond the target. When further compared with three past in-person offerings, students’ creative thinking performance in fall 2020 (under online teaching) is still comparable with those achieved in-person. This again demonstrates that our teaching approaches and practices are helpful to overcome the challenges and barriers presented by online teaching.

6.3STE response

We present students’ teaching evaluation (STE) responses to the question “The instructor held my interest and attention during class” as one indicator of students’ motivation and interest. Participants rated on a 5-point rating scale (5-strongly agree, 4-agree, 3-neural, 2-disagree, and 1-strongly disagree). Students’ ratings in six past in-person offerings and the online teaching in fall 2020 are shown in Table 10. Notice that STE was not conducted at our institution in spring 2020 as a college-wide decision.

The sum of “Strongly Agree” and/or “Agree” scores to this STE question is plotted in Fig. 11, where scores of the six in-person offerings are plotted in blue, the score of the online teaching is in purple, and the average of all seven scores are in red. It can be seen that the STE score for online teaching (fall 2020) is slightly higher than the average.

Fig. 11

STE scores over seven semesters (six in -person vs. one online).

Table 11 shows the same data set prepared for the One-Way ANOVA analysis, which yielded a result of F (1, 127) =0.49, p = 0.484. This revealed there was not a statistically significant difference in students’ interests and motivation between the two groups of students (under in-person teaching and online). This further confirms students’ interest has been successfully maintained/sustained using our course design solution.

6.4Student satisfaction

For the three simulation projects, we collected students’ opinions, via zoom polls, on how each project helped them to understand and implement robotic control algorithms in the corresponding area (autonomous mobile robot, robotic manipulator, and more advanced robotic control). The survey question has four choices: “Absolutely help” (score 4), “Certainly help” (score 3), “Just help to some extent” (score 2), and “Does not help at all” (score 1). Figure 12 illustrates how the survey was conducted and how the results were collected on Zoom, using Project 2 as an example. Via zoom polling, the result is available instantly.

Fig. 12

Illustration of survey of student satisfaction of the simulation projects via zoom polling.

Out of 21 students, 21, 20, and 19 students participated in the survey of the first, second, and third project, respectively. Students’ responses are presented in Table 12.

Using 70% as the target for being “Satisfactory”, both Projects 1 and 2 meet students’ expectations very well. Specifically, more than 80% of the students thought these two projects were absolutely/certainly helpful. The MATLAB-ROS project (Project 3) falls slightly below the target of 70%. Considering the challenge of the MATLAB-ROS project, we think that the satisfaction rate of 68% is actually encouraging for bringing ROS into undergraduate robotic courses or curriculum.

The data presented in Secs. 6.3 and 6.4 are pertaining to students’ responses to one single question, i.e., if their interests and motivation were maintained, and if each of the simulation projects served its purpose. Though only one question was used in each case, the combined analyses of using different indicators agree with each other, thus supporting the conclusion of sustained students’ interests in a joint manner.

In the future, we will include assessment of students’ creative thinking capabilities (given in Sec. 6.2) and the satisfaction surveys (here in Sec. 6.4) as regular and routine activities to collect more data and evaluate our course design approach in the long term. We will also expand these satisfaction surveys to include more questions. For example, the question of asking “Does Project#1 help you understand path planning, navigation, sensor detection, map building, and basic motion control of autonomous mobile robots?” will be break down into several questions: 1) “Does Project#1 help you understand path planning?” 2) “help you understand navigation?”; 3) “help you understand sensor detection?”; 4) “help you understand map building?”; and 5) “help you understand basic motion control?”.