PRE2020 3 Group3: Difference between revisions
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Let’s have a look on how we can simulate the acceleration needed to stop the robot on time. | Let’s have a look on how we can simulate the acceleration needed to stop the robot on time. | ||
Assume we have a robot moving with speed v inside our restaurant assisting our waiters carrying the food and drinks. Suddenly a kid unexpectedly jump in front of the robot; immediately the robot senses that movement through the sensors now it needs to decelerate in time. | Assume we have a robot moving with speed <math> \vec{v}</math> inside our restaurant assisting our waiters carrying the food and drinks. Suddenly a kid unexpectedly jump in front of the robot; immediately the robot senses that movement through the sensors now it needs to decelerate in time. | ||
Unfortunately is fully loaded, breaking with its maximum force will cause the food and drinks to spill, this will cause not only the spilling of food but also a lot of mess, since the robot itself and the restaurant floors will need to be cleaned. As it has become clear this is something that we would like to avoid, so people can receive their orders on time and waiters can continue with serving the customers instead of cleaning. | Unfortunately is fully loaded, breaking with its maximum force will cause the food and drinks to spill, this will cause not only the spilling of food but also a lot of mess, since the robot itself and the restaurant floors will need to be cleaned. As it has become clear this is something that we would like to avoid, so people can receive their orders on time and waiters can continue with serving the customers instead of cleaning. | ||
To achieve this we want to test which accelerations different dishes allow us to brake with. Knowing the acceleration and the range our sensors read at we can decide what the maximum speeds the robots should use for different drinks and food. This way it will not be overprotectivelly slow in cases the dishes can take a harsher stop. | To achieve this we want to test which accelerations different dishes allow us to brake with. Knowing the acceleration and the range our sensors read at we can decide what the maximum speeds the robots should use for different drinks and food. This way it will not be overprotectivelly slow in cases the dishes can take a harsher stop. | ||
=The simulation= | =The simulation= |
Revision as of 15:45, 13 March 2021
[math]\displaystyle{ \usepackage{esvect} }[/math]
Robots in Horeca
Group Members
Name | Student ID | Department | Email address |
---|---|---|---|
Marvin Thüne | student id | Applied physics | m.p.thune@student.tue.nl |
Isidoros Kotinis | 1286692 | Applied physics | i.n.k.kotinis@student.tue.nl |
Lotte van Megen | 1453092 | Psychology and Techonology | l.m.v.megen@student.tue.nl |
Problem statements
To analyze and plan the introduction of service robotics in horeca. We now have three options, after more research and interviews with the stakeholders, we will decide what will be the best route and which project has the most potential.
1. Design a specific situation where robots make it possible to open up Horeca that is hygienic enough to be able to open up during a pandemic. Robots will minimize the customer-staff proximity in the horeca.
2. Look at existing server robots in restaurants and try to improve their customer friendliness by improving their interaction with people and modifying their appearance. Mostly look at server robots, not the ones in the kitchen. Analyze which properties the robots should have.
3. Design a robot that helps people with a disability (or people that are forced to isolate due to medical reasons) to do work in a restaurant by letting them remotely controlling robots that walk around in the restaurant. People who have trouble finding work because they have to stay at home or can’t do much physical work can still find work in this way. This will also make sure the robots can be perceived friendlier by the customers because a real human being is talking to them instead of a computer. The restaurant has robots that walk around and serve the food, the person who is controlling the robot remotely can either be integrated into the robot or be a simulation on each table. These simulation robots then work together with the serving robots.
Objectives
1. Describe a complete situation that would allow most Horeca establishments to open with the help of robots. Simulate this situation to check if the situation will work in real life. Also give the functions and properties the robot should have.
2. Conduct a research about the appearance and behavior a robot should have to come off as friendly as possible. The main part of the research will be about the interaction between the robot and the customers. In the end, recommendations will be given on what the most important parts are for a robot to be perceived as friendly. We are going to look into what the most plausible way of interaction is for the customer; screen interface, face to face interaction etc?
3. Describe a situation where it is possible for people to remotely control the robots in a restaurant. Also design the interface of this robot and how everything should work. We will not only work on the robot itself but also make sure that it interacts well with its environment and that the whole restaurant works well.
USE Analysis: Users/Society/Enterprise
- Restaurant owners: Can use these robots in their establishments and allow them to open up the places again, even during corona times.
- Customers: will receive a better and or different dining experience. They can also get to chance to dine out again, even during the pandemic.
- People with certain disabilities and people who have to isolate: they now have an opportunity to work and keep busy. They get a chance to participate in society, even if it is remotely.
- Horeca workers like chefs: will be able to work again and earn some money.
Needs and requirements
- Guests: the need to eat together en in a friendly and safe (COVID-proof) environment
- Employers: can give new people a chance to work in their restaurant. Can let some of their employees work again, even during corona times. They want to open their restaurants again and be able to earn some more money.
- Other restaurant employees: They can finally work again in corona times. Some of their work can be done by robots so now they can focus on other tasks.
- Customers Managing: Some of their work gets taken out of their hands so they have more time to focus on the customers.
State-of-the-art
For this research, we were looking for different types of robots that already exist and work in the horeca. When looking for robots we discovered that they could be categorized into roughly two types. Firstly the server tray robots, these robots have a purely functional form, the interaction with humans demands a lot of action from the user. The second type looks more humanoid, these robots interact more with the users and look and act more like humans. We did some research on different types of robots and the way they work. They are stated below.
Server tray robots
LG CLOi ServeBot
Type/purpose Serves drinks and small snacks Moving vending machine Very limited personal interaction with the customer
Pros
Large storage -> does not need to be refilled/pickup orders often
Quite robust
Relatively large wheelbase compared to the height
Cons
Needs big open space e.g. casinos, events, convention
A limited selection of products
A large amount of customer effort required
Coronavirus application Limits interaction between cashiers and customers. But bigger conventions are probably not realistic during a pandemic. Thus partly defeating the advantage of using this type of serving robot as a precautionary measure to limit the exposure of staff and customers.
Application after pandemic ends Convenient for some customers that happen to be thirsty or a bit hungry when they spot the bot moving about. Basically, a moving vending machine and might for this reason be economically viable.
LG CLOi ServBot
Type/purpose Moving serving tray Brings orders from the kitchen to customers at the table
Pros Limit exposure of staff to customers Customers can sit at the table and not wait in line with other customers Some personal interaction with customer possible through the screen/speakers Food is ready to be consumed right away
Cons
Needs flat unobstructed space to operate
Some customer effort required -> standing up and taking food from tray
Food is exposed -> losing heat
Potentially limiting the number of orders this type of robot can deliver in a single go without food getting cold
Food on plates limits the acceleration/deceleration potential before food might be displaced
Coronavirus application Useful to limit customer and staff interaction at a fastfood/large open restaurants. If combined with an app customers could go straight to the table to limit their exposure to other people.
Application after pandemic ends Reduces the amount of staff needed at a big-open/fastfood restaurant. Therefore potentially economically viable.
Starship
Type/purpose Food delivery robot Brings orders from a kitchen to customers at a specific location. (Table/home/park etc.)
Pros Limit exposure of staff to customers Customers can sit at table and not wait in line with other customers Or stay at home/in the park etc Food is insulated -> food stays warm for longer Allowing for larger travel distances Robust -> does not tip over easily Low center of mass Large wheelbase compared to height High speed potential
Cons Needs flat unobstructed space to operate Some customer effort required Standing up and taking food from inventory Food in bag so not ready to eat right away Low to the ground -> hard to spot If operating outside, the environment is far less predictable Potentially inconvenient to other users of the infrastructure
Coronavirus application Useful to limit customer and staff interaction at a fastfood/large open restaurants. If combined with an app customers could go straight to the table to limit their exposure to other people. Even staying at home which would be the ideal during a pandemic.
Application after pandemic ends Reduces the amount of staff needed at a big-open/fastfood restaurant. Therefore potentially economically viable. Could potentially replace the current food delivery system.
Bear
The bear robot belongs to the category of server tray robots. There are two different types, Servi and Mini-Servi. They both have 3 levels with plates which can carry different things like drinks and food. The Servi is meant for restaurants and the Mini-Servi is a better fit in bars and for serving drinks. They are easy to install and multiple robots can be used at once. The robot can be controlled with the attached touchscreen or with an external tablet. There is also the option to look at the analytics to monitor and improve the robot. Both robots weigh 33 kg and can carry 30 kg and their battery works for 8 up to 12 hours. The only big difference between them is the dimensions (https://www.bearrobotics.ai/products/index.html).
Humanoid robots
Dadawan
One restaurant in the Netherlands seems to stand out the most when it comes to applying robots in their restaurant. This restaurant is named Dadawan and they already tested out three different robots. One for welcoming guests and two different types of robots for serving trays. They also did some experiments with the robots to see if they could make their restaurant coronaproof (https://www.youtube.com/watch?v=y4k-R5WMmhs,).
Guest are welcomed by a little robot named Jamie that will take their temperature, if their temperature is normal the people can follow the robots to their seats. They have to order their food online via an app and a bigger robot named Amy will then bring the trays with food to their table. Guests have to take the plates from the tray themselves. Not all the work is done by the robots, they mostly do the logistic work. There are still employees walking around, they can now focus on other work and help the guest with different requests. The last robot is Akatar, this robot helps with cleaning everything up. The employees have to place the trays on the robot and the robot will then take everything to the kitchen. (https://www.hartvannederland.nl/nieuws/bediening-robots-restaurant-maastricht).
Both the people from Dadawan and their guests keep emphasizing that the robots really enhance the experience of eating out. The owner of the restaurant, Danny Deng, keeps emphasizing that the robots are not a replacement of his employees but are there to help them. The robots also help to increase customer friendliness according to him because his normal employees now have more time for the guests. Furthermore, they also help with saving time. The robots come with a standard software package but Danny Deng still has some programmers working for him to optimize the program and to implement the floor plan of the restaurant into the robot. Danny Deng also states he has bigger plans and wants to open a restaurant that is fully operated by robots. (https://www.missethoreca.nl/restaurant/artikel/2020/05/horeca-robotica-robots-moeten-gastvrijheid-dadawan-verhogen-101336132?_ga=2.170190368.1208467789.1613485759-24978766.1613485759)
Approach, milestones and deliverables
Work on the interface for the interaction between robot and human. Make it possible to control for as many people as possible. Points we could focus on:
- Robot design
- Requirements on design
- Make a simulation
- Make a concept of the design (supported by psychology research)
- Flowchart for robot decision-making?
- Pathfinding
- To minimize interaction
- Table management
- Interface
- With the customer
- In the kitchen
- (Disabled) Operator
- Serving mechanism
We will also be looking for other aspects of these robots that may cause problems, this will be done by talking with a stakeholder like Dadawan (who already uses these types of robots in their restaurant). If clear problems should arise we will focus on that part of the robot and try to come up with solutions to solve this problem.
Stakeholders
Provisional problem statement: How can you implement server robots in a restaurant in an appropriate way and how can they help with opening horeca during corona times?
We will get in contact with an important stakeholder: Danny Deng, the founder of Dadawan. We will ask them different questions about certain topics like navigation, interaction with people, the ordering system, serving of food, privacy and corona.
The questions will be about different topics, those topics are:
- Navigation
- Interaction between the robot and human
- Ordering system
- Serving of food
- Privacy
- Corona
Interview with Dadawan
To get to know more about the specific problems that come with implementing robots into a restaurant we held an interview with an important stakeholder. This stakeholder is Paul Seijben, he works for the restaurant Dadawan. Dadawan was one of the first restaurants that actively used robots in their restaurants, they are now one of the frontrunners in this field in the Netherlands. Dadawan imports the robots from a factory in China so they dont know all the technical details about the robots but they have worked and experimented with them for some time now.
Our goal for this interview was to discover if there were any big problems that they encountered while using these robots and if we could maybe come up with solutions or suggestions for them. The conducted interview is written out down below, the answers are not quotes but globally what he told us. The points that we got out of it will be discussed in the next section.
Q: What made you decide to work with robots? What was your motive?
A: Danny (the owner) traveled to China a lot and discovered these robots. In China, way more restaurants use these robots already. He contacted the factory and imported a few robots straight away. The main reason why we wanted to implement these robots in the restaurants was to help our employees, they have to work with very heavy plates so using these robots could make carrying them easier.
Q: Does the robot meet your expectations?
A: It was harder than we initially thought to implement these robots in our restaurant. The suppliers always tell you the best points only of course. Especially the mapping and programming. We even hired a freelancer to help us with programming the robot. The robot Jamy also didn’t work for us, the whole process of bringing people to their tables and taking their temperature took way too long for when it is busy. Taking the temperature also didn’t work once there were people standing behind them.
Q: You now have two robots in use, Amy and Dexter, what are your experiences with them?
A: Amy looks more human and is more interesting to our guests. We see that this especially works well for marketing and on things like social media. Amy is less functional than Dexter but Dexter gets less attention from the guests. The efficiency could still improve for both of them, together with their navigation. They are still quite slow and walk around very rigidly, we would like to see them more flexible in the future. The biggest problem was that they are unable to communicate, so to avoid collisions we could only send out one robot at a time.
Q: How do you set up the robot? Is it all ready when it arrives?
A: We expected it to be easier to set up the robot but it turns out that the mapping of the restaurant is quite hard still and we still had to program a lot of things ourselves. It would also be easier to implement them into a restaurant that was designed for robots, we now had some extra challenges because of this. Asking the supplier about our problems was also quite hard because of the language barrier.
Q: What would you like to see improved about the robots, what are the points of improvement? A: It would be nice to see them improve on navigation as I said before. We also contacted the factory because we would like to have the option to control the robots from something like an apple watch. Right now our servers have to walk to the robot or the kitchen to give it its orders. It would be nice if we could do this without having to walk back every time. Because we have these heavy plates it would be great if these robots would follow us with the plates. This way we don’t have to walk back to the kitchen 4 times if we have an order for 8 people, we could just take all these plates to the table at once. It would also be nice if the implementation of the rootings would be made easier, right now we had to hire a programmer to do this for us.
Q: What is the main point of added value these robots bring you?
A: Amy works well for marketing especially. Right now they only cost us money and our employees don’t really trust them yet and are hesitant to work with them. But we want to keep working with them and keep improving their efficiency.
Q: Would you see options to use these robots during the pandemic?
A: we did some experiments with them and they worked quite well, the only downside was that our hospitality goes down if guests’ only interaction is with robots. We think people would agree to this during the pandemic but it has no further future after that for us.
Q: How did your employees find working with these robots?
A: At first they were really hesitant. Most horeca employees aren’t really technical, they just want to work with people. This bumped a bit at the beginning but we think that once our employees trust the robot more than the collaboration will improve a lot. Our employees should be able to trust the robot to do its tasks and do them well.
Q: What is the reaction of the guests when they see your robots?
A: They mostly find it interesting to see how it works. Right now we don’t see these robots as replacements for our employees they just add something interesting to the restaurant. The reactions online can sometimes be negative, people say this is absurd and that our hospitality suffers from these robots.
Q: What is your ultimate goal with these robots?
A: I am a bit more skeptical than Danny. We just want to experiment with this product, but we also depend on the technical world. As long as these robots don’t really work like we would like them to it is hard for us to implement them into our restaurant of course. We can only keep trying and investing in them and hope for the best. in the end, we hope to have 3 robots per restaurant to help our employees. This would also require more trust in these robots from our employees.
Experimental Setup
Let’s have a look on how we can simulate the acceleration needed to stop the robot on time.
Assume we have a robot moving with speed [math]\displaystyle{ \vec{v} }[/math] inside our restaurant assisting our waiters carrying the food and drinks. Suddenly a kid unexpectedly jump in front of the robot; immediately the robot senses that movement through the sensors now it needs to decelerate in time.
Unfortunately is fully loaded, breaking with its maximum force will cause the food and drinks to spill, this will cause not only the spilling of food but also a lot of mess, since the robot itself and the restaurant floors will need to be cleaned. As it has become clear this is something that we would like to avoid, so people can receive their orders on time and waiters can continue with serving the customers instead of cleaning.
To achieve this we want to test which accelerations different dishes allow us to brake with. Knowing the acceleration and the range our sensors read at we can decide what the maximum speeds the robots should use for different drinks and food. This way it will not be overprotectivelly slow in cases the dishes can take a harsher stop.
The simulation
Our focus lays on what is happening to the trays and more specifically on them; Let’s have a look! Since the trays are attached to the robot they will uniformly move with the same speed [math]\displaystyle{ \vec{v} }[/math]
Planning
Week | Planning |
---|---|
Week 1 | Come up with different ideas |
Week 2 | Look up some research papers and try to find a specific topic to focus on |
Carnival break | Come up with plan for this project |
Week 3 | Work out the plan and search for stakeholders |
Week 4 1 - 7 March | Hold interview with stakeholder which will give more answers and show us what the greatest problems are |
Week 5 8 - 14 March | Work on deliverable, do research and try to find ways to make it possible, look for ways to setup the experiment |
Week 6 15 - 27 March | Do the experiment |
Week 7 22 - 28 March | Work out the experiment and work on calculations |
Week 8 29 March - 4 April | Work on the report, final presentation (video or online) |
logbook
student | Task | Time spend |
---|---|---|
Together | Had lecture and tutorial, began to look for groups to join | 3 h |
student | Task | Time spend |
---|---|---|
Together | Had a meeting with the group, thought about interesting topics, Had an introductory meeting with our tutor about topics we were interested in | 1h, 0.5 h |
student | Task | Time spend |
---|---|---|
Isidoris | ||
Marvin | ||
Lotte | Introduction research about the state of the art + researching specific topics | 2h, 2h |
Together | Three meetings discussing the research we did about the state of the art, and trying to come up with plans.
Also working on the wiki. |
0.5 h, 2.5 h, 1.5 h |
student | Task | Time spend |
---|---|---|
Isidoris | Looked up robots and specifications: Amy & DEXTER | |
Marvin | Worked on the questions for the interview | |
Lotte | Work on wiki put everything in a clear oder, type out the results of the research that was conducted, send email to dadawan (stakeholder) | 3h, 0,5 h |
Together | Meetings | 2h, 1h |
student | Task | Time spend |
---|---|---|
Isidoris | Fill in log book, Requirements, Sectors that can be improved and their problems, possible solutions, main takeaways | |
Marvin | Fill in log book, experiments and solutions for speed/efficiency vs dish/drink stability | |
Lotte | Put planning and logbook in wiki, type out the answers for the interview and put them in the wiki | 2h, 2h |
Together | Meeting with stakeholder + two group meetings | 2h,1 |
student | Task | Time spend |
---|---|---|
Isidoris | ||
Marvin | ||
Lotte | ||
Together |
student | Task | Time spend |
---|---|---|
Isidoris | ||
Marvin | ||
Lotte | ||
Together |
student | Task | Time spend |
---|---|---|
Isidoris | ||
Marvin | ||
Lotte | ||
Together |
student | Task | Time spend |
---|---|---|
Isidoris | ||
Marvin | ||
Lotte | ||
Together |