Today’s students are increasingly immersed in a digital landscape. Their primary source of experience is now mediated through mobile screens and laptop monitors instead of direct interactions with the physical world (Alvermann, 2004; Morley, 2001). This new reality has important implications for science pedagogy in general and physics education in particular (Crompton et al., 2016; Strimel & Grubbs, 2016; Tang & Tsai, 2016; Weintrop et al., 2016).

A cornerstone of science education is the establishment of links between general theories and the application of those theories to specific phenomena in the everyday world. To ensure that science students continue to be engaged, educators must renew their repertoire of classical examples with digital-era ones that are more relevant to the new world in which students now live.

For today’s students, the everyday world of physics is no longer the experience of sliding down a ramp or throwing a baseball: it is more about noticing how their smartphone screen automatically transitions from portrait to landscape mode. Indeed, smartphone behaviours of this type are the starting point for the kind of digital-transition project we will be describing in this paper.

The digital revolution has produced a vast array of information-technology (IT) tools that are transforming the way we communicate with and deliver content to students, independent of the subject matter. This type of transformation has been and will continue to be widely discussed in the education-research literature (Blazer, 2008; Fies & Marshall, 2006; Schindler et al., 2017) but is independent of the digital transition we discuss here: The former transformation changes the manner in which content is delivered, whereas the latter involves a change in the content itself. The former involves adapting and then using tools made possible by technology; the latter, as we shall presently explain, incorporates into the curriculum an understanding of digital technology itself and its associated data-processing paradigms.

A major impediment to the latter transformation is the fact that curriculum content is, to borrow a term from game theory, a zero-sum game: If we add new content related to digital technologies, we usually have to remove some traditional content to make room for it. The strategy is to conceive of examples of digital-world behaviours that illustrate traditional scientific concepts. In this manner, we keep the traditional content intact, replacing only traditional examples with digital-era ones.

Our challenge, then, is to find, within the ideas and concepts of digital technology, examples that illustrate classical physics concepts. The project in our case study does exactly that by carefully designing activities in which students examine modern smartphone behaviours that illustrate fundamental physical principles.

The general potential for smartphones to enhance the classroom experience has been discussed widely (Buck et al., 2013; Langan et al., 2016; Park et al., 2012), including in the present journal (Mammadova, 2018). This has been investigated for some time within the physics education research community: earlier attempts examined handheld devices, such as the Nintendo Wiimote (Hochberg et al., 2016), with the much more versatile smartphone devices (Arribas et al., 2015; Monteiro & Martí, 2016; Tornaría et al., 2014; Vieyra et al., 2015), including tablets (Egri & Szabó, 2015), quickly becoming of greater interest.

The project we will discuss here builds on these initiatives and has itself been described in various international journals (Hinrichsen & Larnder, 2018; Larnder, 2019a, 2019b; Larnder & Larade, 2019). It has also been extensively promoted locally (Larnder, 2018a, 2018b; Larnder & Portelance, 2018, 2019a, 2019b), and in some cases (Larnder, 2019c; Moon, 2018), has been published in both official languages. It provides a series of laboratory activities that rely on the accelerometer motion sensors found in current-generation smartphones. An additional digital-era component is found in the laboratory apparatus used for each activity, since they are built using 3D-print technology.

The Quebec government has long recognized the need for stimulating and supporting systemic change in its educational system. At the college level specifically, it administers a number of programs[1] which have been increasingly geared towards digital literacy. Our case study, for example, is in its 4th year of funding under such programs.

The Quebec government recently deployed its Digital Action Plan (MESS, 2018), an ambitious multi-year project for carrying out a digital transition across the entire Quebec educational system. It recognizes three broad categories of activities and investments, as listed in Table 1.

The framework as a whole is quite comprehensive. Indeed, it can for this reason serve as a checklist even for stakeholders evaluating projects that are not directly funded by it, such as the one we describe here. The last orientation in the table, which accounts for a large portion of the budget, pertains to infrastructure investments, some of which, as we shall explain below, would be particularly effective in achieving the digital-technology development goals of the project that we shall be examining here.

Accelerometer sensors were quickly identified as a promising category of device for students to explore. The concept of acceleration is ubiquitous in physics, but students often have difficulty with it, and most laboratory activities only obtain acceleration values by performing calculations using data related to the position of objects. Accelerometers are devices that can measure accelerations directly, potentially making the concept of acceleration more accessible to students. They are widely used for mobile motion sensing, including smartphones, sleep-monitoring and fitness-monitoring devices.

Recent advances in micro-electromechanical (MEMS) sensors (Gardner et al., 2001, chap. 8) have made these devices small, inexpensive and accurate enough to produce reliable results. A wide variety of stand-alone accelerometer devices were acquired and tested for reliability, configuration options and workflow usability.

Smartphones also host accelerometer sensors, and an increasing number of apps available enable students to view and collect the data from them. By the end of the first year of trials, it was clear that smartphone apps on both Android and iOS platforms were reliable and supported a simple data workflow. Smartphones quickly became the device of choice for laboratory activities. An additional element of student engagement was gained through the pride and fascination students experienced in using their very own familiar smartphone devices for an entirely new purpose.

The first promising activity involved an examination of the familiar portrait-landscape transition that automatically occurs when changing the orientation of a smartphone. This takes place typically when using photo-viewing or texting apps. Students are instructed to carefully measure the critical angle at which this transition takes place, and to interpret the corresponding output of the actual accelerometer sensor used by the smartphone to track such orientations. By examining the accelerometer data, students deduce the critical angle that they had originally measured by other means.

The activity is a digital-age replacement for the classical example widely known as “the inclined plane.” The same fundamental physics concept is covered: the decomposition of the gravitational vector into components along the axes of an inclined frame of reference─in this case, the frame of reference of the smartphone. Additional skills include understanding the difference between global and local coordinate systems, and the determination of the angle of a component-form vector as summarized in Table 2.

A second successful laboratory activity involved spinning students’ smartphones and examining the resulting acceleration output. Student engagement was elicited, this time, by the vague sense of danger produced in seeing their beloved phones spinning quickly. The accelerometer output, in this case, demonstrates the principle of centripetal acceleration, a quantity that exists even when an object is rotating at a uniform rate.

A particular insight arises in the students when they are able to conclude that, regardless of where they place the phone on the rotating surface, the acceleration vector always points towards the center of rotation. In addition, they can carry out some bona fide digital-era reverse engineering: By putting together the results achieved when the phone is placed in several different positions, they are able to deduce the exact location of the accelerometer sensor within the body of the phone. They can then obtain circuit diagrams of their own smartphone model to obtain visual confirmation of the result they obtained.

For the portrait-landscape experiment, an apparatus dubbed the “TiltTray” was developed; a set is depicted in Figure 1. It holds smartphones of a variety of shapes on an inclined place that can be set to any desired angle. It has a built-in protractor for accurate direct measurement of the angle of incline.

For the spinning smartphone, another apparatus was developed. Dubbed the “SpinFrame”, it consists of an 8-1/2-by-11-inch rectangular frame that perfectly admits a standard piece of paper, and on top of which is placed the smartphone. The frame prevents the phone from slipping off the rotating surface and provides reference positions to measure from. The frame sits on top of a record player adapted to the purpose.

Both of these apparatuses are in fact “mixed-media” objects: The TiltTray requires a conventional protractor to be glued into place on the 3D-printed surface; The SpinFrame has a motorized base that is bought off-the-shelf in the form of an inexpensive record player. One of the consequences is that some assembly is required, and therefore, parts, materials and assembly instructions need to be documented.

Each lab activity is refined in an iterative manner by running pilot projects with individual students and adjusting the written lab instructions accordingly. Additional iterations take place with full classrooms of students, at which point the activity is made available to other teachers for adoption. The first early adopters were the project initiators’ colleagues within the same Physics department. The next ones were teachers in the Engineering Technologies program of the same college.

As the instructions became more advanced, they began to be made available to teachers at other colleges for extramural adoption. As usage grew, variations and improvements on the original lab activity occurred. These became new resources to share within the network of participating colleges, contributing to the overall collective benefit. Table 3 summarizes the historical usage to date of the two sample labs described above.

The two activities described above cover the classical topics of inclined planes and circular motion. Additional lab activities continue to be developed using the same digital-era tools. These include experiments involving exploration of oscillations; development of 3D spatial reasoning for the purpose of understanding magnetic phenomena; and identification of hand-drawn alphabet symbols from accelerometer signals.

The use of 3D-print technology to design and produce supporting equipment for lab activities opens up an exciting new category of sharing and collaboration among colleges. Adopting colleges can now not only download and print (paper) instructions for lab activities, but also the (3D-printed) equipment that the students will be manipulating during those activities. A freely-available resource package contains all the necessary documents described in Table 4.

Such a forward-looking vision was made possible only because of the technological lead of the college[2] hosting the project: It had already invested in a dozen 3D printers for its Engineering Technologies program, including a large-volume printer; and had acquired the valuable skills of lab technicians in calibrating and maintaining the equipment and in assisting students and faculty members in their use.

Indeed, this novel delivery model (paper-printed instructions plus 3D-printed equipment) assumes a certain level of 3D-print capability in adopting colleges, which involves both investing in 3D-print equipment and in training staff to operate it effectively. Such capability is only beginning to emerge within the college network. Four years into the project, all equipment is still being produced using the 3D-print farm at the hosting college and lent on a temporary basis to the external early-adoption colleges. Initial 3D-print trials have taken place at three other colleges[3] in the network, but none are yet at the capability level of producing a full-classroom set for their exclusive internal use.

As discussed previously, the advancement of the 3D-print component of the project, and thus of the project as a whole, depends on the degree of 3D-print capability within the college network. Although no systematic evaluation of this capability has been undertaken, current project experience suggests that it has been generally lacking; and that, in this sense, the project appears to be lamentably ahead of its time.

With the recent deployment of the Digital Action Plan, however, the situation looks altogether different. Section 3 of the Plan (see Table 1), representing the bulk of the funding, concerns network-wide investments in infrastructure, wisely combined with a freedom granted to individual institutions in making strategic choices in equipment purchases. One of the potential areas of investment for colleges lies in building up their 3D-print capability.

This has the potential of producing a valuable symbiotic relationship. For the project at hand, it reduces the barrier to adopting the lab activities: It becomes attractive and inexpensive when both lab instructions and lab equipment can be printed locally. For the architects behind the Digital Action Plan, it ensures investment choices that contribute to visible and world-class uses of technology in a classroom setting, all the while ensuring equal accessibility for even the most remote 3D-print-capable locations within its geographical territory.

From the point of view of college administrators, the project is a rare but welcome example of some of their infrastructure investment being used for a purpose that is both tangible and visible: There is a concrete image of their own locally-printed laboratory equipment being used for the benefit of engaged students learning physics through the use of their own smartphone sensors.

3D-print capability involves much more than just the acquisition of equipment. Both teachers and support staff need to develop skills in using 3D modeling software in order to specify the shapes to be printed, and become familiar with the workflow from 3D modeling file formats to the final printed object. A key element is training support staff in the calibration and maintenance of the equipment, as well as in the management of the various print requests and of the supply of 3D filament.

Administrators need to ensure that their investment can benefit a large number of stakeholders effectively; and, hopefully, find ways to foster collaborations among departments and among categories of employees. Indeed, in our case study, three of the currently-participating colleges have teachers working closely with lab technicians in the development of their 3D-print capability. The project has also stimulated significant collaborations between the departments of Physics and Engineering Technologies at one college[4], and between the departments of Physics and Industrial Design in another.[5]

The project, therefore, can serve i) as a stimulus for adapting and integrating personnel into the new workflow implied by 3D-print technology; ii) as a concrete example of a comprehensive 3D-print project that is purposeful and pedagogically oriented; and iii) as a model and creative stimulant for future projects within such educational institutions.

This case study presents us with an interesting situation in which one type of innovation ( 3D-printed equipment ) is co-developed in support of another innovation (lab activities using smartphone sensors). Although there are significant interactions between their parallel and interdependent development, they nevertheless follow two broad phases characteristic of most educational-innovation projects.

In the establishment phase, projects begin with ideas and sketches; are elaborated as prototypes; are iteratively tested and improved, first through pilot programs with individual students, and later with individual teachers in a classroom setting. In the elaboration phase, they are shared with more practitioners, usually in the same department or college as the project initiator. An important milestone is the adoption of the innovation by practitioners outside of the initiating college. The extramural adoptions (see Table 3), in turn, bear witness to the value of the innovations, and signal a level of project maturity in which a plan for broader deployment within the college network can be considered.

Each developmental phase involves new priorities for the further development of the project. In the first phase, the emphasis is in providing teachers with the resources needed for carrying out the laboratory activity itself. In the second phase, one obstacle to further elaboration is the need to support the development of 3D-print skills in teachers and support staff. These two concerns correspond to the two categories of resources identified in Table 4. In the broader deployment phase, this bottleneck lies, as discussed, in the availability of 3D-print equipment in the adopting colleges.

It is instructive to interpret these development challenges in terms of the framework provided by the aforementioned Digital Action Plan. Indeed, as summarized in Table 5, it is clear that the Plan is comprehensive enough to account for all the categories of support identified in this Discussion.

Small low-cost MEMS accelerometer sensors are still a relatively new technology. After four years, projects have resulted in many explorations of their use in the analysis of a wide variety of motions. Only a small subset of those opportunities have been selected as appropriate for introducing fundamental physics concepts at the college level.

The accumulation of more advanced motion-analysis ideas has resulted in a new spinoff project (Larnder, 2019d) that defines a promising new area of fundamental research. It involves machine-learning techniques for interpreting accelerometer data and is funded independently of the present project (Fonds de recherche Nature et technologies, n.d.). It benefits students not in a classroom setting but rather through their individual participation in research tasks. Some additional contributions to digital-era pedagogy are likely to arise from it, in the form of educational activities involving computational techniques and the use of machine-learning frameworks (Larnder, 2020).