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An office chair was equipped with four force transducers, located at each corner under the seating. These four sensors make it possible to compute the center of Pressure (COP). “Only four force transducers are required to estimate characteristic parameters for quantifying the biomechanical effect of a certain sitting posture.” This allows to monitor the sitting position of an office worker. | An office chair was equipped with four force transducers, located at each corner under the seating. These four sensors make it possible to compute the center of Pressure (COP). “Only four force transducers are required to estimate characteristic parameters for quantifying the biomechanical effect of a certain sitting posture.” This allows to monitor the sitting position of an office worker. | ||
=Where We Continue= | =Where We Continue= |
Revision as of 19:15, 22 March 2020
Group members
David van Son | 1005864 |
Susanne Louvenberg | 1238843 |
Jur Janssen | 1247069 |
Bas Ohlen | 0963529 |
Jeroen Meijs | 1008703 |
Tutor Meeting Questions
Het schrijven van de requirements blijft lastig. Zijn de punten die er nu staan goed? En aan welke andere requirements moeten we denken?
Is het experimental plan beschreven op de wiki goed? Wat is nog onduidelijk en te verbeteren?
Als aankomende week het prototype af is, was het plan om een user test te doen (zie experimental plan). Door de situatie is dat eigenlijk onmogelijk. Hoe kunnen we dit het beste oplossen?
Problem statement
In our current society is the sitting position the most frequent body posture, especially in the office working industry. Many professions require working behind a desk. Students also experience those working conditions. Jans, Proper, and Hildebrandt (2007) found that working adults in the Netherlands can spend up to 12 hours sitting down on a workday[1]. Because people are sitting more hours a day, much research is done to determine the consequences of sitting for longer periods of time.
There has been done research about long-term health risk of long occupational sitting[2]. Health risk as body fatness, cancer, type 2 diabetes, cardio-vascular disease, and mortality are examined to their connection with occupational sitting. However, they conclude that there is insufficient evidence of a causal relationship between those conditions.
However, other research does shows that occupational sitting increases pain. Medical and ergonomic field studies indicate that sitting posture can be the cause of muscle, connective tissues of tendons, ligaments, and join capsules pain[3]. Chronic pain and troubles may be the result of static load for longer periods of time. The degrees of pain increased as the time of occupational sitting increases. A study by Womersley, L and May, S (2006) showed that people with backache sat for longer periods of uninterrupted sitting compared to the no backache group of people[4]. The sitting posture also determines the effects of occupational sitting. In their same study the group with postural backache also had a more flexed relaxed sitting posture. Other research confirms this result because slumped sitting position and poor shoulder posture (e.g. rounded shoulders, and head forward) causes pain due to mechanical changes that affect the function of the median nerve[5]. Shoulder protraction reduces the nerve movement and other joints are moved. In response to moving other joints, the nerve dynamics is altered which changes the local blood supply. This is harmful for the nerve function and causes the risk of neck and shoulder pain.
Backache and neck pain are one of the most frequent cause of invalidity in industry in most Western countries[6]. Kuoppala and colleagues (2008) showed in a systematic review that promoting ergonomics and a good sitting position reduces the absences from work[7]. This stresses the importance of a good sitting position, because it reduces pain for individuals but also decreases work absences for the company.
Marshall, and Gyi (2010) mention: “Environmental influences such as no support for the feet, low-friction seating material, or poor desk height can all create additional muscle work. Poor design forces the adoption of awkward and inefficient working postures that can ultimately lead to discomfort, pain, and chronic disability if adverse conditions persist.”[8]. In addition to the environment influencing the sitting posture another research states that individuals with neck pain have a different perception of a ‘good’ sitting position[9]. Their sitting position is slightly different, and even a small change in head position can result in an increase of the lead on supporting structures and muscle activity[10]. This indicates that it is important to impose a sitting position on people to accomplish a good sitting position that decreases the chances of pain.
To conclude, it is of importance to have a chair that provides a good sitting position to reduce the effects of occupational sitting. However, every person has a different physique, which means that one chair would not fulfil the needs of different users. Most chairs can be to some extent be adjusted at the users wishes. But as stated above, users who experience backache do not always have the correct idea of a ‘good’ sitting position. In the current working environment, employees do not have a fixed sitting position because of flex-work spaces. Therefore, the user needs to adjust the chair every day to have a good sitting position. To overcome all the problems stated above, this project envisions an automatic chair that helps the user with establishing a good sitting position.
Additional Papers
The following list consist of other papers that confirm the problem statement and are of relevance to this project.
- Posture plays an important role in performance. Poor posture can lead to worse task performance while also adding stress to the spine and balance muscles [11] [12].
- Posture is also a tell-tale sign of engagement, it is even possible to estimate engagement purely on posture [13].
- This paper studied two groups, symptomatic and asymptomatic office workers. All subjects demonstrated an 10% increase in forward head posture from their relaxed sitting postures with the computer display. No substantial evidence for posture changing over a working day was found. [14].
- The high complain of musculoskeletal disorders is due to awkward postures, unsuitable workstation and lack of knowledge related to the areas to apply in everyday routine and it shows that working postures have a direct contribution on musculoskeletal disorders complained by the office workers in Putrajaya. [15].
- Given the association between RULA (Rapid Upper Limb Assessment) score and the prevalence of the problems, reducing RULA score by designing ergonomic workstation may reduce the prevalence of WMSDs (work-related musculoskeletal disorders) among the workers. [16].
- Computer usage increases risk of developing musculoskeletal disorders. Such an increase is mediated by ergonomic factors such as mouse use, remaining seated for prolonged periods, adoption of inadequate or uncomfortable postures, performing certain PC tasks, and psychosocial factors. [17].
=Our Solution='
To overcome all the problems stated above, this project envisions an automatic chair that helps the user with establishing a good sitting position. This chair has the possibility to automatic adjust the sitting position of the user. When the user wants to use the automatic chair, he or she needs to login. This is to know which user uses the chair and therefore which unique position chair needs to take. This can be done by scanning the user’s student or company card. Besides some other personal information, this card will have some details about your body part lengths. With this information, the automatic chair can adjust the sitting position for a particular user in the best sitting position to overcome backache.
Scenarios
The following two scenarios describe the importance of this project and the end user that is envisioned.
Fleur studies the bachelor Applied Mathematics at the TU/e. She needs to attend lectures and study for many hours a week to learn the courses. This means she spends about 5 hours a day on occupational sitting. Her days consist of meetings, lectures, and individual studying, which means she switches from different chairs very often. However, she does not take the time to adjust the chair to her optimal sitting position. Most of the time, Fleur only changes the height of the chair. But she started to notice that she is experiencing backache. She realizes this pain is coming from a bad sitting position. Therefore, she is enthusiastic about the new automatic chairs on the University. Since the new chairs arrived Fleur has been using the automatic chair every time, which is easy for her because of the login system. She is experiences way less backache compared to before. The chair made it easier to adjust the chair which she did not completely did before. Besides, the automatic chair made her more aware of her sitting position.
Thomas is 56-year-old and works already 30 years at the Rabobank. He has a job which requires him to work behind a computer every day. He experiences occupational sitting for around 8 hours a day. In the past, Thomas experienced shoulder and neck pain. However, he searched for help and understood it was because of the many hours sitting in a bad position. From then on, he started to adjust to chair as much as possible to have a better sitting position. He has been doing this for almost 10 years already. As a result, he experiences far less backache than before. But a few years ago, the Rabobank started to use flexible working spaces. Which means Thomas needs to switch places every day. This is very annoying for him, because he needs to adjust the chair each day again. Because he does this in the most optimal way, it takes him 5 frustrated minutes. Thomas would really like to see the automatic chair in his office. This means he does not have to struggle each day with adjusting his chair.
Objectives
There are different types of users involved in this product. The primary user is most important for this project. The primary users are in this case the office workers and students. This is because they frequently experience occupational sitting for longer periods of time.
Primary user objectives
- The user can ‘activate’ the chair to automatically go in the good sitting position.
- The user can manually change the sitting position of the chair.
- The user can use the chair like a regular chair, and thus without the automatic option.
- The user understands what the sitting cues indicate.
- The user knows how to sit in the correct good sitting position.
- The user can adjust their incorrect sitting position to the defined good sitting position with the given cues.
Survey
A questionnaire was done to examine the primary user’s perspective of our project. This survey consisted of questions regarding the users sitting behavior and about our solution to a bad sitting position. The goal of this survey was to find out whether the user would like to use such an automatic chair to begin with. It also served as a start to know the focus of this project.
The survey can be divided into three parts based on the questions that were asked. The first part are questions about how currently people adjust seats and sit on them. The second part is about what the participant would want to in a chair. Thirdly, questions about what our product could do to help them sit in a good position and what the user would want. It is important to get an idea of the current situation and the preferences of the user. Besides, the results are important to find out what people would actually want.
The survey is linked here.[1]
Results
The results are linked here.[2]
Questions about the current situation
In the survey, it was asked whether users change workplace often or not. The participants gave mixed answers. Some switched chairs often, but most people do not seem to switch chairs that much. It was also asked whether the participant is aware of their sitting position. Only half of the people indicated to be aware of this. But only a third actively changes their bad sitting position. 40% of the users said they adjusted their seat often, another 40% said they did not adjust their seat at all, and the remaining 20% said they adjust it sometimes. The height of the chair was mostly adjusted. The armrest was the second most important and the back of the chair coming in third. When people adjust their seat, only a few of them spend a minute or more on the adjustment. The overwhelming majority spends much less than that.
Questions about what they would want
The survey showed that people would prefer to have their own personalized chair. Logically, people preferred an adjustable chair over a nonadjustable chair. Participants wanted to be able to adjust their chair. Height was most important followed by the arm rests and the back rest.
Questions specifically on the automatic chair
It was asked if people would be fine with a server that keeps data on users’ preferences and their location. Almost all participants replied that they would be fine with that. A few of them has some concerns about privacy and would only allow it if the data was anonymous. Half of the participants found an automatic system convenient, and the other half also saw the benefits of a good sitting position. After the automatic seat adjustment, almost all people want to have the option to adjust their seat manually. Most people would want to make use of the automatic chair.
Conclusions
When looking at how people sit, it can be concluded that users are not very concerned about their sitting position. Most people do not seem to actively do something about their position. A reason can be that users are most concerned with comfort rather than the effects of occupational sitting. The answer on which sitting position they have, as well as the fact that more users adjust their seat than care for it, support this.
When adjusting, the most important thing is the height of the seat, followed by the armrests and the backrest. When designing our product, these will be the most important parts of the chair that need to be changeable.
It can be concluded that convenience is an important factor that should be taken into account in designing the automatic chair. This is supported by the fact that all of the participants liked the convenience of an automatic system.
Our Goal
The survey provides some important remarks about the automatic chair. It stands out that users want to manually adjust the chair after it has been automatically changed into the good sitting position. Users mentioned this is important because: ‘the position of the chair can be experienced as not comfortable’. Another questioned showed that users have many different sitting positions. Of which not many people follow the backrest.
This started a thought process. Engineers can design the best automatic chair which will change to the perfect sitting position, but can it be assumed that the user will sit on this chair with a good sitting position? Probably not. The results of the survey show that users will adjust the chair and/ or will sit in a relaxed bended position. The goal of the automatic chair is to reduce the pain caused by occupational sitting. The automatic chair is designed to provide the user with a chair that helps to sit in a good position. However, the next step is to make sure the user uses the chair as intended and stays in this position.
As can be read in the problem statement, pain caused by a bad sitting position is common and can be reduced by accomplishing a good sitting position. Reducing occupational sitting pain is our main objective. There is already done some research about the systems that make the automatic chair. This is described in the section State-of-the-Art. Because of that, the focus of this project shifts into the second design step of making sure the user stays in this good sitting position.This includes registering the users sitting position on the chair, knowing whether this is a good sitting position, and finally giving a cue to the user if this is not a good sitting position.
Product Requirements
The following list of requirements help to structure the project process and ensures traceability. These are the requirements for the prototype. This includes a pressure sensor mat that measures your sitting position. But also, some type of cue that will let the user know when they have a bad sitting position. Other requirements would need to be added, if the list was about the whole automatic chair.
- The sensors need to hold up to a weight of 100kg.
- The sensors cannot be felt by the user.
- The user understands the meaning of cues after explaining it once (9 out of 10 users).
- The user voluntarily uses the automatic chair (9 out of 10 users).
- The user does not experience the sitting cues too annoying to use another chair (9 out of 10 users).
State-of-the-Art
The automatic chair can be build based on three systems. Firstly, a log in system in the chair which will provide the information about the user that is using the chair. Secondly, the system needs to know what a good sitting position is for this particular user. Thirdly, this information will be used by the system to automatically change the position of the chair. There already has been done research about all systems, separately or combined. Here an overview is provided about current research relevant to the project.
Memory device for a user profile
For the automatic chair a login system is envisioned to make it easy to adjust the chair for a particular user. Such system can already be found in many technologies, as for example: TU/e printers, AH bonus card, and Android Multiple User. Another example is the memory device for a user profile of devices in a motor vehicle [18]. This innovation: “is used for providing data corresponding to the user profile in the vehicle without a user having to make corresponding settings.” This memory device is useful because it consists of personal data but also activation data for the vehicle. In the case of this project, the vehicle could be the chair. This memory device may be used independently of a vehicle and is therefore very flexible to use.
Ergonomic guidelines for a chair
Much research has been done about what the good sitting position is. A paper by Zheng, Dorsey and Miltra (2014) describe the ergonomic guidelines for an ergonomic chair. [19]. Those guidelines are listed below.
- The seat of the chair should have the correct height. Both feet should be supported. When a chair is too high, it creates undue pressure at the knee and thigh. While, if it is too short the knee will be higher than the hip sockets.
- Width and depth of chair seats should conform to the user’s dimensions.
- Flat un-contoured seats are preferred to discourage a slouched or C-shaped posture.
- Lumbar support by providing low- or mid-back support can help hold good posture and prevent pain to the spine and neck.
- Head support, if provided, can help ease stress for the neck muscles and provide support for seating over extended periods.
- Arm rests provide support for reading, typing, painting, and similar activities.
Research on ergonomic design and evaluation of office backrest curve
This other paper forms a good basis to establish a chair with a good sitting position [20]. This paper conducted a survey which gave interesting insights. Results showed that the most used sitting posture is the ‘relax’ posture seen in Figure ??. The survey shows that 50.3% of the subjects considers the backrest as very important. As part of the backrest, the waist support causes pain in the back when sitting in an office chair for a longer period for 58.09% of the participants. Followed by the neck support part of the backrest which causes for 57.23% of the participants pain in the neck. The backrest inclination angle (36.01%) and the hardness/ softness (31.83%) of the backrest are also causing discomfort. Thus, when the back of the user cannot fit well in the backrest due to shape and material, it eventually will cause neck and shoulder pain. This paper concludes that the backrest is the most important part of an office chair.
A test was done to see whether the shape of an office chair corresponds to the shape of a spine. The results of the chair and spine measurements can be seen in Figure ??. The shape of the spine of an average person can be seen, together with the shape of the four tested chairs. This shape is divided into three parts: head and neck, back and thirdly the waist. None of the four chairs is similar to the human spine when sitting upright. All the chairs do have a waist support, but not fully consistent. The most serious differences are at the head and neck area, but also the upper back is not well supported. This shows us that most of the existing office chairs do not follow the shape of the human spine. This research also showed that the chair backrest is mainly used for relaxation. It plays a small role in supporting the user while working. It is suggested to design the back of the chair according to the shape of the human spine to support the human body while working. It is of importance to match the curve of the back of the chair with the shape of the spine in the sitting position.
This paper concluded with the following ergonomic requirements for an office chair.
- Headrest height: 628.3 – 675.1 mm. (ranging from the normal height for females to that of males with high cervical spine point in a sitting posture).
- Waist support height: ≥ 210 mm.
- Waist support depth: 20 – 40 mm.
- Effective back width: ≥ 360 mm.
- Seat back height: ≥ 460 mm.
Active approach to improve ergonomics
In this paper an active approach is made to improve ergonomics by combining sensing and self-actuating workspace furniture [21]. Posture sensing, ergonomics reminders, and active furniture were combined to improve ergonomics. Possible options of posture sensing are:
- Accelerometers in wearable devices that can track partial body postures.
- Flex sensors that can detect head tilt and arm angles.
- Capacity sensors and piezoelectric sensor used in chairs that can detect bad postures on pressure distribution.
- Vision-based monitoring systems that can detect sitting postures.
- Geometric features can determine incline angle of user’s head.
- Face detection that can calculate the distance between face and screen.
- Microsoft Kinect sensors that can provide skeletal tracking, measuring the user’s body dimensions.
This study made a prototype of an automatic chair including ergonomic reminders. There is a real-time feedback displayed on the screen. This guides users on how to adjust the chair position and height for a good sitting position. This product is an active furniture that uses a motorized desk for automated height adjustments. In addition, dual robotic arms provide automated adjustment based on sensor data on height and distance. The ergonomic guidelines that were used are: (Figure ??.)
- Maximum forward head tilt of 15°. (1)
- Upper arms are vertical, and forearms are horizontal. (3, 4)
- Thighs are horizontal, and knees are at 90°. (5, 6)
- Vertical viewing angle of 15-20° below the horizontal, with the first line on the screen below eye level. (2)
The paper mentions that only a prototype was made and it needed improvements to become a real product. One suggestion as future work was to conduct an extended field study. This would be needed to observe the deviation from the initial postures. We also envision an active approach supporting continuous posture and activity monitoring for helping users maintain ergonomic postures throughout the day.
Automatically adjustable office and task chairs
Already back in 1996, Google placed a patent on their designed automatically adjustable chair [22]. Their innovation is capable of five electrically powered position adjustments. But in all cases, the user is able to adjust the chair himself. This is: “to reduce the strain of sitting in exactly the same position of extended periods of time and reduce repetitive motion injuries”. This chair also has a memory device. This way multiple users can quickly adjust the chair to a preselected position. The idea behind is to make minor adjustments to the users position over periods of time to again reduce the strain.
A system for posture monitoring and guidance
This article has as goal to improve the sitting behaviour of office workers [23]. People are usually not aware of their (statically) sitting behaviour and posture while working concentrated on a task. An intelligent office chair was designed that measures the users sitting posture and whether this person sits statically. With effective feedback, the chair will guide the user with sitting in a more dynamic and healthy way. The chair is equipped with four force transducers, that detect the sitting posture of the office worker. If an ‘unhealthy’ posture is detected, an alert directs the user to sit in another way.
This research focuses to detect a certain posture but mainly to estimate the biomechanical effect a certain sitting posture. It turns out that there are two important parameters: “the time a person sits statically, and another important parameter is the force acting on the spine which is closely related to the flexion and extension angle of the lumbar spine”.
An office chair was equipped with four force transducers, located at each corner under the seating. These four sensors make it possible to compute the center of Pressure (COP). “Only four force transducers are required to estimate characteristic parameters for quantifying the biomechanical effect of a certain sitting posture.” This allows to monitor the sitting position of an office worker.
Where We Continue
As can be read above, there is already quite some knowledge that is needed to make the automatic chair. Because of that, this project assumes an automatic chair that is envisioned can be designed and produced. To continue the research, our focus will be the second design step of making sure the user stays in a good sitting position in this automatic chair.
Our research question is:How can the user be stimulated to stay in a good sitting position indicated by the automatic chair..
Possible Solutions
There are many different ways the user could be stimulated to keep a good sitting position. The possible solutions mainly differ in the amount of autonomy of the user. One solution could be to launch an information campaign that raises awareness of the problem. This option leaves the user with the most autonomy. In this case, the user would be able to decide for himself whether he actively adjust his behavior because of the information. Another solution which involves a seating police limits the autonomous decisions of the user way more. Imagine a scenario where citizens monitor each other. In our case, this seating police would consist of many normal users, who could watch others whether they are seating like they are supposed to. A warning or punishment could be given to force people to sit in a healthy way. While these solutions are on the ends of the spectrum of user autonomy, there are also more balanced options. These solutions came down to warning the user of their bad seating position, either actively or passively. This way the user remains their autonomy for the most part, while being nudged in the direction of a healthy seating position. The following list consists of possible solutions.
Informing
- Raise awareness and informing people about a healthy seating position.
- Measure the current way the user sits and give information on how to improve.
Nudging
- Built a display in the chair which shows if you have the correct sitting position.
- Built a light in the chair which shows if you have a correct sitting position.
- Notification on your phone which reminds you of your sitting position.
- Let the chair vibrate if the user does not have a good sitting position.
Paternalism
- An auditory stimulus to let the user know it should keep the good sitting position (similar to seatbelts in a car).
- A blocking system on your computer that only allows the user to use the computer when it has a good sitting behavior.
- A seating police.
Conclusion
Based on the survey held in week 2, it can be seen that users are already aware of their bad sitting position. This indicates that a lack of awareness is not the problem. Therefore, an information campaign would have little to no effect to solve the bad sitting position of users. It was also already mentioned that users would like to always have the possibility to adjust the chair, which indicates that they value their autonomy. Those users would probably not like to sit on an actively warning chair. If the encouragement for keeping a good sitting position is to annoying and/ or frustrating for the user, the user would probably sit somewhere else. This will most likely result in them sitting unhealthily, which is opposite to the goal. These findings point out that a chair which encourages the user to keep a good sitting position would be best. A solution which involves passively warning the user would be most suitable.
Measuring The Sitting Position
To passively warn the user of their bad sitting position, it is required to measure the sitting position of the user. This can be done by using a pressure sensor map. This mat can be put on the office chair. This way it will not be needed to make a whole new chair. Inside the pressure mat sensors will be placed equally divided in a 3 times 3 structure. Andreas Schrempf et all. (2011) have shown that the sitting position can be determined by using 4 pressure sensors. However, it is also that the more sensors the more precise the sitting position can be determined. Because of that, this prototype consist of 9 sensors.
Pressure sensors
Load cells [24]
Load cells have different kind of ranges, there are loads cells that have a range of 5-10 kg (55mm x 12.7mm x 12.7mm), but also up to 200 kg (150mm x 38mm x 24mm). The working of a load cell is not ideal for our situation. On both sided (up and front) a piece should be mounted. Then a force will be applied on one plate than the straight bar will deform and based on the deformation the pressure can be translated into an electrical signal. The price of load cells ranges from €10 - €15. [[3]]
Force transducers [25]
Force transducers are used for dynamic, short-duration static and impact force measurements. It can measure tensile and compressive forces, this can be option for our product. The maximum compression is about 80kg, this enough because the transducers will be divided over the whole seat. The dimensions are 19.05mm x 15.93mm. [[4]]
Force sensing resistor [26] [27]
A force sensing resistor (or force sensitive resistor, FSR) is a material whose resistance changes when a force, pressure or stress is applied. These FSR’s have a maximum range of 10kg, it is not sure if this is enough. The weight of a person will be divided over the whole seat, so if enough resistors are used than 10kg can be enough. There are different kinds of resistors. A square FSR (44x38mm) of €9.95 or a circular (12.5mm) of €6.95. [[5]] There is also another one, this one is much more expensive, €21.95. But this one has a much bigger range because the resistance can be adjusted, the maximum can be set up to 300 kg. [[6]]
Conclusion
The choice will be between the circular resistor with a diameter of 12.5 mm or the square resistor with the dimensions 44x38mm. For this project it is better to pick the bigger sensing resistor, because the image of the pressure distribution will be the clearest.
Pressure mat material
The material for the pressure mat is also important. This material must be comfortable because a person will sit on the mat. Also, the FSR's will be places in this mat. It is a requirement that the FSR’s will not be felt by the user, and thus must the material be able to fulfill this requirement.
Polyether SG35 or SG40
This material is often used for seat cushions and the hardness is medium. The material is very cheap for a 300x400x30mm piece the price is €1.80.
Koudschuim HR40
This material is often used for chairs and matrasses. The material is very cheap for a 300x400x40mm piece the price is €3.00. Minimum height is of this material is 40mm.
Conclusion
It does not really matter which of these two products is chosen for the prototype. Both materials are sufficient. Polyether SG40 is chosen for this project. Two thin mats can be bought to place the FSR's between those mats.
List of Materials
Product | Quantity | Price |
---|---|---|
Force Sensing Resistors | 9 | €114.35 |
Foam, SG40 | €18.43 | |
Luidsprekerkabel | 25m | €15.85 |
Tape | ||
Prototype
Building the Prototype
The materials listed above where ordered. It was important to first have the mat to place the pressure sensors in between. The polyether SG40 was cut into the mat of 50x45 cm. This was around the average size of a seat. Then, the positions of the resistors where marked. The pressure sensors where placed in a 3x3 matrix with the same length between each sensor. To connect the pressure sensors with the Arduino, ‘Luidsprekerkabel’ is used. This cable is cur into the right length. At this moment, the wires are soldered to the pressure sensor resistors. Finally, the sensors are placed on the mat with double-sided tape. However, this tape does not stick very well on the material of the mat. It was found that regular duct tape works better, but not very well. To make sure the wires stay at the same place, cuts were made in the foam mat. This way, the wires are placed into the mat which was very stable.
Circuit
The circuit diagram is shown in [7]. The circuit makes use of a voltage divider structure. This divides the voltage between the pressure sensor and the resistor. Since the pressure sensor's resistance increases when the force increases, the voltage across it also increases. This voltage is measured by the Arduino's ADC, which it then outputs to the PC as a value between 0 and 255 (1 byte). The analog multiplexers (MUX) enable us to use more than 6 different sensors.
Experimental plan
Introduction:
To keep the user in the design process of the smart chair system, different experiments are done to determine the most optimal settings. The experiments are based on a study done for the National Highway Traffic Safety Administration of the US[28]. In this article the effectiveness of seatbelt reminders is tested. There are 5 different settings that are tested (basic reminder, continuous flashing, periodic reminder, aggressive reminder, one long reminder) each of these approaches is tested on three different parts. During the experiment the effectiveness, annoyance and attention getting of the signal setting is rated by the test subject and after the experiment a questionnaire is filled in for effectiveness desirability and preference.
At the end of the experiment the participants commented on different signals. They found that the best way to give a visual reminder is a system that gets progressively brighter or flashes increasingly over time. The best acoustic signal is a voice message that comes on periodically and a close second is a non-voice noise that does the same thing. The participants also desire a way to customize the signal to their own preference.
The conclusion of the experiment was that the more annoying the signal was the more effective the response of the participant. Also the desirability of each system in relation to annoyance is different for each participant, some favour the more annoying systems while others desire the more nuanced system. The use of only a visual signal is not effective and should always be supported by an auditory signal. A visual signal should always be flashing because a static visual signal will not attract attention. The main difference in this study in comparison with our system is that the signal should not be so annoying that the user is not willing to use the chair. One of the requirements states that 9 out of the 10 users find the cues not to annoying and uses the chair voluntarily. This is something is experimented in this user test.
The first experiment is to find what kind of signal will give the best results. The second is a qualitative study of the system, where we ask for the opinion and remarks of the user to further improve the settings.
Experiment 1
Goal of the experiment
The goal of this experiment is to find out what is the best way to let the user (the person sitting on the chair) know that they need to change their sitting position.
Description of experiment
The participants take a seat on a chair with the prototype placed on it in front of a laptop, they are informed on what the prototype does and that a cue would inform the user that they should reposition. To simulate a work environment they are asked to fill in a simple sudoku during the experiment, this is so they are focused on the computer as they would be in normal conditions. Then different methods of signalling are tested and the participants are asked to rate each method.
1. Vibrating of the chair in regular intervals of 20 seconds
2. A constant vibrating of the chair
3. A blinking light
4. A constant light
5. An acoustic signal in regular intervals of 20 seconds
6. With a pressure map of the chair
All four of the signals will be tested and the user will grade the signal on a scale of 1 to 5 for each statement, as can be seen below. The experiment will be repeated to get a confident result.
At the end of the experiment the participants are asked if they have any remarks or idea’s on the signal procedure.
Results
The results will be collected and the best way will be chosen. The signal has to be both effective and desirable, because it is wanted that the users will sit in the correct way but not that it is too annoying that the users will not use the chair. The best result will be used in the next experiment.
Experiment 2
Goal of the experiment
With a better idea of what kind of signal to use to get the best results, the experiment continues with a qualitative study. This means the users use the system and ask for their opinion and remarks for further improvements. This way we can optimize the timing, duration and design of the system.
Description of experiment
The prototype is placed in normal working environment (flex workplace, library, etc.), and people are asked to sit on the prototype while working or studying. The signal will go off when they need to readjust their posture. After 15 minutes, the participants are asked to answer the questions that are stated below.
1. What did you think of the sensitivity of the system (the time between when the user sits in the wrong position till the signal is given)?
2. What did you think of the duration of the signal?
3. What did you think of the intensity of the signal?
4. What did you think of the comfort of the prototype?
5. Are you willing to use the system if it is properly introduced?
6. Do you want to be able to turn the signal on and off?
7. What did you think of the visualisation feedback?
8. What do you want to change in the system?
9. What do you like in the system?
10. Do you have any further ideas or improvements to the system?
Results
The results will be collected and the system settings will be tweaked to the needs of the users.
Planning
Below a small week to week planning for the project:
- Week 4: Finish the programming and electrical scheme, order all the parts for the prototype.
- week 5: Build and test the prototype.
- week 6: Do the experiments and collect results.
- week 7: Process the results and begin on the presentation.
- week 8: Finish and prepare thepresentation
Approach
Our approach is that we start by gathering information regarding our topic, the state of the art and the relevance of our research. We will then hold a survey among people who use adjustable chairs often, in which we want to find out which part(s) of the chair they most often adjust. Using this data, we will research which parts are in most need of being monitored. Then we will determine possible ways of warning the user, and make prototype(s) of these systems. We will then test which way is preferred by the user, and which way gives the best results. Combining these results, we will conclude which way would be best for a user warning system.
Milestones
- Evaluation of the best working posture.
- Made and held the survey
- Determined the most relevant adjustable parts of a chair
- Determined the sensors that are needed to detect a person’s working posture.
- Made a prototype of the user warning system
- Full test evaluation of the user warning system
- User evaluation of the user warning system
Deliverables
- This Wiki page containing all our research and findings.
- Survey results about the adjustable chair.
- A prototype of the user warning system.
- Test and user evaluation of the user warning system.
- A presentation at the end of the project.
Who is doing what
Week 1
Name | Time spent | Break-down |
---|---|---|
David | 11 h | Introductory lecture (2h), Brainstorm (1h), Studied papers (4h), Wrote summary (1h), Group meeting (2h), formatting wiki page (1h) |
Jur | 10 h | Introductory lecture (2h), Group meeting (2h), Studied papers [7-10] and made summary (4h), Brainstorm about possible topics (1h), Approach/Milestones/Deliverables (1h) |
Jeroen | 9 h | Introductory lecture (2h), Group meeting+brainstorm (2.5h), Studied papers(4h), Made user requirements (0.5h) |
Bas | 9 h | Introductory lecture (2h), Group meeting (2h), Brainstorm (1h), Studied papers, Update wiki(4h), |
Susanne | 10.5 h | Introductory lecture (2h), Brainstorm (0.5h), Group meeting (2h), Studied papers (2h), Wrote problem statement (4h) |
Week 2
Name | Time spent | Break-down |
---|---|---|
David | 8.5h | Tutor meeting (0.5h), Group meeting1 (1.5), rewrote approach, milestones and deliverables (2h), Group meeting2 (1.5h), Enquête (2h), data analysis (1h) |
Jur | 12h | Tutor meeting (0.5h), Group meeting (1.5h), [Search papers, summarize, make ready for Wiki, put on Wiki] (8h), enquête (2h) |
Jeroen | 12h | Tutor meeting (0.5h), Group meeting 2x (3h), research in ergonomics (4h), make a script for optimal position of the chair(4.5h), |
Bas | 7h | Tutor meeting (0.5h), Group meeting1 (1.5h), Group meeting2 (1.5h), enquête (2h), Made enquête (1.5h) |
Susanne | 10.5h | Tutor meeting (0.5h), Group meeting1 (1.5), Made enquête (1h), Group meeting2 (1.5h), Enquête (2h), Wrote objectives and requirements (3h), Wrote our solution (1h) |
Week 3
Name | Time spent | Break-down |
---|---|---|
David | 18h | Group meeting1 (1.5h), data analysis of survey (2h), add survey to wiki (0.5h), rewrite approach, milestones and delivarables (0.5h), Group meeting2 (1.5h), design electric circuit (2h), make prototype of circuit and program arduino (8h), write code documentation (2h) |
Jur | 11h | Group meetings 1 and 2 (3h), Tutor meeting (0.5h), Research sensors -> what is already used -> which is the best for us (5h), Research material mat (1h), Write parts for sensor and mat on the Wiki (1.5h) |
Jeroen | 10h | Group meetings 1 and 2 (3h), Tutor meeting (0.5h), Research into different sensors to use (6h) |
Bas | 11h | Group meetings 1 and 2 (3h), Tutor meeting (0.5h), Brainstorm (2.5h), Survey results (5h) |
Susanne | 13h | Tutor meeting (0.5h), Group meeting1 (1.5h), Rewrite our solution, Rewrite requirements (1h), Write two scenarios (1h), Group meeting2 (1.5h), Rewrite state-of-the-art and add papers (4h), Write our goal (1h), Write where we continue (2h), Upload wiki and change reading order (0.5h) |
Week 4
Name | Time spent | Break-down |
---|---|---|
David | 10.5h | Tutor meeting (0.5h), Group meeting1 (1.5h), Group meeting2 (1.5h), Update visualisation software (6h), write README document (1h) |
Jur | 7.5h | Tutor meeting (0.5h), 2x Group meeting (3h), Find and order materials (2h), Update wiki page (conclusions and material list) (2h) |
Jeroen | 7.5 h | Tutor meeting (0.5h), 2x Group meeting (3h), start on experimental plan (4h), |
Bas | h | |
Susanne | 8h | Tutor meeting (0.5h), Group meeting1 (1.5h), Group meeting2 (1.5h), Add research papers and finish state-of-the-art (4.5h) |
Week 5
Name | Time spent | Break-down |
---|---|---|
David | 10.5h | Tutor meeting (0.5h), Group meeting1 (1h), Working on prototype (5.5h), Group meeting2 (1.5h), work on prototype software (2h) |
Jur | h | Tutor meeting (0.5h), Group meeting1 (1h), Working on prototype (3.5h), Group meeting2 (1.5h), Write prototype part (1h), |
Jeroen | 9h | Tutor meeting (0.5h), Group meeting1 (1h), do research in annoying signals (2.5h), Rewrite experimental plan(2.5h), preperation for experiment(2.5h), |
Bas | h | |
Susanne | 10h | Tutor meeting (0.5h), Group meeting1 (1h), Working on prototype (5.5h), Rewrite objectives (0.5h), Rewrite requirements (1h), Group meeting2 (1.5h), Add Tutor Meeting Questions |
Week 6
Name | Time spent | Break-down |
---|---|---|
David | 14.5h | Group meeting (1h), Finish prototype (10h), User test (1.5h), Test and debug latest software (2h) |
Jur | h | |
Jeroen | h | |
Bas | h | |
Susanne | 7h | Group meeting (1h), Adjustment to requirements (0.5h), User test (1.5h), Read and make adjustments to the whole wiki page (2.5h), Add new article in state-of-the-art (1.5h), Add Tutor Meeting Questions |
Week 7
Name | Time spent | Break-down |
---|---|---|
David | h | |
Jur | h | |
Jeroen | h | |
Bas | h | |
Susanne | h |
Week 8
Name | Time spent | Break-down |
---|---|---|
David | h | |
Jur | h | |
Jeroen | h | |
Bas | h | |
Susanne | h |
References
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- ↑ Dilley, A., Lynn, B., Lees, R., & Julius, A. (2004). Shoulder posture and median nerve sliding. Bmc Musculoskeletal Disorders, 5(1), 1-7.
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- ↑ Kuoppala, J., Lamminpaa, A., Husman, P. (2008). Work health promotion, job well-being, and sickness absences—a systematic review and meta-analysis. J Occup Environ Med, 50(11), 1216 -27.
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- ↑ Edmondston, S., Chan, H., Chi Wing Ngai, G., Warren, M., Williams, J., Glennon, S., & Netto, K. (2007). Postural neck pain: An investigation of habitual sitting posture, perception of ‘good’ posture and cervicothoracic kinaesthesia. Manual Therapy, 12(4), 363-371.
- ↑ Harms-Ringdahl K, Ekholm J, Schuldt K, Nemeth G, Arborelius UP. (1986). Load moments and myoelectric activity when the cervical spine is held in full flexion and extension. Ergonomics 29, 1539-52.
- ↑ Straker, L. M., Pollock, C. M., & Mangharam, J. E. (1997). The effect of shoulder posture on performance, discomfort and muscle fatigue whilst working on a visual display unit. International Journal of Industrial Ergonomics, 20(1), 1-10. doi:10.1016/S0169-8141(96)00027-3
- ↑ Sahu, M., Alfred Sunny, K., Kumar, M. W., Baburao, G., & Gnanasaravanan, S. (2019). Effect of work postures on the musculoskeletal stresses on computer aided designers and office staff working on computer in india. International Journal of Scientific and Technology Research, 8(11), 1120-1123. Retrieved from www.scopus.com
- ↑ Nomura, K., Iwata, M., Augereau, O., & Kise, K. (2019). Estimation of student’s engagement based on the posture. Paper presented at the UbiComp/ISWC 2019- - Adjunct Proceedings of the 2019 ACM International Joint Conference on Pervasive and Ubiquitous Computing and Proceedings of the 2019 ACM International Symposium on Wearable Computers, 164-167. doi:10.1145/3341162.3343767 Retrieved from www.scopus.com
- ↑ Szeto, G.P.Y., Straker, L., Raine, S. (2002). A field comparison of neck and shoulder postures in symptomatic and asymptomatic office workers
- ↑ Mansor, C.H.C, Zakaria, S.E., Dawal, S.Z.M. (2013). Investigation On Working Postures And Musculoskeletal Disorders Among Office Workers In Putrajaya
- ↑ Choobineh, A., Tabatabaei, S.H., Tozihian, M., Ghadami, F. (2007). Musculoskeletal problems among workers of an Iranian communication company
- ↑ Ortiz-Hernández, L., Tamez-González, S., Martínez-Alcántara, S., Méndez-Ramírez, I. (2003). Computer Use Increases the Risk of Musculoskeletal Disorders Among Newspaper Office Workers
- ↑ Flick, B. (2009). U.S. Patent Application No. 11/918,852.
- ↑ Zheng, Y., Dorsey, J.N. Miltra, N.J. (2014). Ergonomic-driven Geometric Exploration and Reshaping
- ↑ Zhang, Y., Luo, L., Wang, J., Hu, H., Zhao, C. (2020). Research on Ergonomic Design and Evaluation of Office Backrest Curve. Capital University of Economics and Business, Beijing, China. SAMR Key Laboratory of Human Factors and Ergonomics, China National Institute of Standardization, Beijing, China.
- ↑ Wu, Y.C., Wu, T.Y., Taele, P., Wang, B., Liu, J.Y., Ku, P., Lai, P.E., Chen, M.Y. (2018). ActiveErgo: Automatic and Personalized Ergonomics using Self-actuating Furniture. National Taiwan University. Texas A&M University
- ↑ Rogers III, M. W., Bogart, B. E., Gerke, D. L., Eberle, R. A., & Thomas, C. (1996). U.S. Patent No. 5,556,163. Washington, DC: U.S. Patent and Trademark Office.
- ↑ Schrempf, A., Schossleitner, G., Minarik, T., Haller, M., Gross, S., & Kurschl, W. (2011, August). PostureCare-Towards a novel system for posture monitoring and guidance. In 18th World Congress of the International Federation of Automatic Control (IFAC) (pp. 593-598).
- ↑ Moriguchi, C.S., Sato, T.O., Coury, H.J.C.G. (2019). An Instrumented Workstation to Evaluate Weight-Bearing Distribution in the Sitting Posture. Federal University of São Carlos, Physical Therapy Department, São Carlos, Brazil.
- ↑ Schrempf, A., Schossleitner, G., Minarik, T., Haller, M., Gross, S. (2011). PostureCare - Towards a novel system for posture monitoring and guidance. Upper Austria University of Applied Sciences, School of Applied Health and Social Sciences, Medical Technology. Upper Austria University of Applied Sciences, School of Informatics, Communications and Media.
- ↑ Ohlendorf, D., Maurer, C., Bolender, E., Kocis, V., Martha, S., Groneberg, D.A. (2018). Influence of ergonomic layout of musician chairs on posture and seat pressure in musicians of different playing levels. Institute of Occupational Medicine, Social Medicine and Environmental Medicine, Goethe-University.
- ↑ Zemp, R., Taylor, W.R., Lorenzetti, S. (2016) Seat pan and backrest pressure distribution while sitting in office chairs. Institute for Biomechanics, ETH Zürich
- ↑ Lerner, N., Singer, J., Huey, R., aand Jenness, J. (2007). Research Boulevard Rockville,