72 = 2 × 2 × 2 × 3 × 3 = 2 3 × 3 2. Using a prime factorization calculator like the one here may employ a different algorithm, but the resulting factorization will be the same. It is also possible to arrive at the same prime factorization of 72 by starting from 4 x 18 and then repeating the process for each of those values. Prime Factorization to a Factor Tree While prime factorizations are unique, there might be several ways to represent the factor tree for any given prime factorization. In the example above, we discussed how a prime factorization could be determined by dividing small primes, or, in the case of 72’s factorization, by starting with larger composites such as 4 x 18. Either approach produces the same factorization, but the route taken is different.
A factor tree documents the path taken to reach the prime factorization, showing each division step along the way. Each branch in the factor tree shows the split of two factors, which may or may not be primes. If a number is composite, the tree extends below it. Depending on how many possible non-prime factors there are, there may be a large number of different factor trees that could be drawn for the same prime factorization.
Dad’s prime factorization calculator produces a factor tree for the prime factorization of 72 as shown below. This factorization calculator takes the approach of trying to find factors near the square root. This makes the factor tree shown in the calculator’s answer much clearer, even though this approach may not mimic exactly what you get when producing a prime factorization by hand. Regardless of whether you use the calculator or determine the answer by hand, the factorization will be identical. And the calculator itself is much more interesting to work with, especially with larger integers! What Can You Do with a Prime Factorization? Among other things, you can use two prime factorizations produced by this calculator to help determine the least common multiple (LCM) or the greatest common factor (GCF).
This calculator provides some great ways to conceptualize prime factorizations, but if you’re looking for another perhaps less useful but more artistic perspective, be sure to check this link out More Calculator Resources There are a number of other calculators on this site designed to help further your explorations of mathematics and number theory. Be sure to check a few of them out! Apart from the prime factorization calculator on this page, you can find other math calculators in the ‘Tools’ menu in the upper right. Try a few at the links below!
Prime Factorizer
Prime Factorization Calculator is an online tool for number conversion programmed to calculate the number of prime factors for a given number. In mathematics, factorization or factoring is the decomposition of a number into a product of other objects, or factors, which when multiplied together give the original. For small numbers you can calculate the prime factors simply. When it comes to large numbers, finding out the prime factors may be time consuming and bit complicated.
To make your calculations easy, this online prime factorization calculator will help you to figure out all the prime factors in the given number by a single click.
Number factorizer (a.k.a. Integer factorization calculator) computes prime factors of a natural number or an expresssion involving + -. / ^! Operators that evaluates to a natural number. The result of the number factorization is presented as multiplication of the prime factors in ascending order. If result of the expression evaluation is a prime number then the number itself is returned. To check that a number is a prime the should be used since it supports larger numbers.
Factorization Examples Please if you have any suggestions on how to make Number Factorizer better. Math tools Number properties Choose language: - powerful math tools for everyone. By using this website, you signify your acceptance of and. © 2018 numberempire.com All rights reserved.
There’s a new version now, with more functions! Yesterday was the last day of our school year, so it’s finally time to relax! And by relax, I mean write code.
I was thinking about the tasks I want to set for next year, and wanted to find a tool to help create sketches of graphs. Not plots of graphs: there’s for that. No, I mean a bare sketch that shows only the most important points. It doesn’t need to precise, but it does need to be clear, and easy to copy. I searched for a while, but couldn’t find anything that was really what I wanted.
There are plenty of tools that can do the job, but not without a bunch of messing around first. So I decided to write my own. Introducing: the.
To be honest, the code behind it is kind of a mess, and it’s extremely limited, but it works. Mess around with it yourself to see what it does. Basically, it draws a parabola based on the location of the vertex and one other point.
The vertex and the “second point” can be dragged wherever to set the parabola’s position, while the “third point” will position itself on the existing parabola when dragged. The axes can be moved by dragging the whole sketch. Each of the points can be toggled invisible, have labels added, and can be “locked” to the axes. When you’re done, click the download button to save your graph as a SVG file. To be clear, this is not intended to be a learning tool, and the target audience is not students. I made this purely to help myself create graphs for assignments, and I’m sticking it online because I figure other teachers might find a use for it as well.
The use case I see for this is the rapid creation of a graph that can put into an assignment or quiz paper. It saves as a vector image, so it won’t create big ugly pixels when printed as can happen when a graph is created from a screenshot. One thing I happily discovered today is that SVG files can be directly inserted into a Word document.
I’m not going to promise it works perfectly. I’ve really only tested it with Chrome, so use that if you want the best chance of it working properly.
I did also have success in Firefox, but Microsoft Edge has problems with the download feature. The most obvious drawback to the whole thing is that it only does quadratics. I do want to modify it to support other types of functions, but I’ll leave that for another day. This is just a hobby project, so I’m not sure if I’ll spend much more time on it.
That said, I do have some ideas about what I want to do (especially with adding other functions.) If you’ve got any suggestions, I’d love to hear them.
Over the last summer. Part of this is my focus on parent functions through the first part of the year, giving students a solid understanding of each function and their transformations. To help focus on the fundamental properties of each function, we used the following template each time we introduced a new function. Importantly, I had the students figure out details as a class. After stating the rule for the function, we always filled in the two-sided number line, with inputs on the top and outputs on the bottom.
I chose to use a number line instead of a table, as it allows me to point out the continuous nature of the values between each mark on the line. Then we filled in the domain and range, examining the inputs and outputs to determine these.
We also determined if the function is one-to-one or many-to-one. I’m really proud of how my students have become increasingly confident in determining these answers for themselves from their own understanding of the functions and their values.
Next, we plotted the function on the grid. The number line is deliberately aligned with this grid to help students make the connection between the two. I have a SmartBoard template set up with points along the x-axis, with which we move points up or down to plot the function, to emphasize how the graph demonstrates the connection between input and output values.
Then knowing the shape of the graph allowed us to easily fill in the rest of the table. The inverse function section depended on which function we were talking. Sometimes we filled it in immediately, as most students understood x² and √x as inverses. Other times we waited to fill it in, such as with exponential functions which was completed before we talked about logarithms. The second part of this template are the two “Graphing Example” section inside. In the past, I’ve found students resistant to showing all the algebra they needed when they sketch a graph (usually because all they wanted to do was copy what their calculator showed.) I wouldn’t say this template has completely changed that, but it has made a big difference. Students complained a bit at the start of the year, but they’ve learned to appreciate the guidance this provides and gained a lot of confidence in their graphing ability.
I know students probably don’t need to find the transformations of the parent function for every graph they sketch, but I think having them do this for each question we practice has helped their understanding of why each function produces the graph it does, and has helped serve as a check for the other parts of the template. We’ve often had to leave the x-intercept section blank, because we’ve started graphing each type of function before we looked at solving equations involving that function. This has actually worked out pretty well. I found students accept my explanation that “We can’t do this yet because I haven’t taught you how.” Then, when we come solving those equations (typically the very next skill), I can use the need to find x-intercepts as a motivation for practicing solving equations. Then we go back to our graphing examples, find the x-intercepts, and add that detail to the graph. My students are sometimes annoyed that we jump backwards in our notes sometimes, but I think they appreciate that I’ve tried to avoid overwhelming them with too many details they don’t need to see all at once.
That’s been my approach all of this year: the idea that students don’t need to see all the detail until they’re ready for it. For instance, while we’ve talked about quadratic functions, we’ve only dealt with the vertex form, as that’s the form that can be explained through transformations, fitting the function pattern we’ve been following.
Yes, we still need to talk about factoring, distributing and all that fun stuff. But now I feel we have a structure to build everything else on. I’m actually looking forward to completing the square this year, as I have a really useful motivation for it: it allows us to put quadratic functions into the form my students are already very familiar with.
We’ve introduced our last parent function now, so I’m not going to get any more use out this template this year. To be honest, I felt a little sad when we finished our last one, because it’s worked so well this year. Also, it means I’ll actually have to produce notes for each lesson now, instead of using the same ones over and over again Included is a second version that leaves out the parent function template for a third graphing example.
Below you can find all the parent functions from my notebook for this year, as well as a couple of the graphing examples pages. Linear Function Absolute Value Function Quadratic Function Square Root Function Cubic Function Cube Root Function Rational Functions Exponential Function Logarithmic Function Graphing Examples. I’ve decided to make functions the key focus of the first few units of Algebra 2 this year.
I mentioned this in my: This year, the start of the Algebra 2 course is going to focus on functions, transformations and inverses. For quadratics that means only dealing with vertex form, as well as showing the relationship to square roots.
We’ll cover all the functions that way, before coming back to all the other algebra we missed along the way. So we’ll cover quadratics again, including all the factoring and solving stuff. With that in mind, I thought I’d better make sure my students understand what a function is. This is the front, basically just explaining what a function is. The examples on the bottom section were actually done after the notes inside. You could really use any examples you wanted.
I chose these ones because this first unit focuses on absolute value functions, and I figured they should at least be able to evaluate quadratics, even if they don’t know anything else about them yet. This is the part I’m most proud of. I think it lets students see clearly what the difference relation types are. I know it’s traditional to talk about the vertical and horizontal tests in this situation (and I did mention them briefly), but I decided to go back to the basic definitions of one-to-one, etc. And let students develop an understanding from those definitions.
I was glad that by the time we did the last few diagrams, students were suggesting what the diagrams should be without any prompting. Though they sometimes have to be prompted with “does each output have exactly one input,” most students have been good at recognizing the difference between one-to-one and many-to-one, which is critical as inverses are coming up soon. They often get many-to-one and one-to-many mixed up. They know which is which, they just get the names confused.
I had a student say at one point, “So, it’s the number it goes from to the number it goes to, right?” Then after realizing what she’d just said, added “Oh, I guess that makes sense.” So, at least one of them has made that connection! I know that it’s typical to make a mistake as a teacher and just claim it was to “see if you’re paying attention,” but in this case, having to cross out the bit that said “function” for one-to-many and many-to-many really was deliberate. (I promise I’m not just saying that!) Making students have to edit the page like this was an attempt to drive the point home that these are not functions. Thankfully, some of my students did notice that these sections contradicted the notes on the front of the foldable, and suggested it needed changing before I did. This is the second skill for Algebra 2, which is pretty much what it says in the title. At this point, we’re almost ready to start talking about functions, but I wanted to “review” a few things about solving equations first.
Which brings us to these pages. Except, lets just pause for a moment, and examine those quotation marks around “review”.
The linear equation stuff is straight-up review, but solving absolute value equations is one of those used-to-be-in-2-but-now-in-1 topics. Which means it’s new to my students this year, but should be something my future Algebra 2 students have already seen. With that out of the way Nothing terribly complicated here. These should be equations my students know how to solve, but as I suspected would be the case, they needed some help shaking some of the cobwebs loose first. I find students get a lot more frightened of linear equations than they need to be, especially when fractions start showing up. This was a good chance to have them use a strategy that shows up again and again in algebra: If you don’t know how to solve this problem, turn it into one you can solve.
And that’s the principle behind the design of these notes. Each situation shown really only requires one or two steps to turn it into an equation like the one above.
I would never suggest teaching this stuff for the first time like this. There needs to be much more time spent developing understanding at each stage. But for review, I think it worked fine.
I very purposely didn’t use “cross-multiplying” as the final strategy. Those words are banned in my classroom. While it could solve the example shown, cross-multiplying is useless for any problem involving more than two fractions, for instance. Every so often, I have a student suggest cross-multiplying as a way to solve a problem. Never have any of them been able to apply it the way they were supposed to. So, I’d rather my students take one more step to solve an equation and actually understand what is happening, rather than totally confuse themselves.
Absolute value equations are not in the Algebra 2 standards, but I wanted to include them anyway, because:. These students missed them in Algebra 1. (Which means I’m supposed to cover them anyway.).
AFAIK they’re on the ACT. They’d be some pretty easy points my kids would be throwing away if they didn’t know this. I’m about to use absolute value functions as an example for transformations and graphing, to set up everything we’re going to do with other functions. It’s probably a good idea if they knew how to find some x-intercepts, then.
I think it’s going to be useful to expose students to equations that can have two, one or no solutions. I heard a rumor that there’re these things called quadratics that do something similar. I also wanted kids to practice finding extraneous solutions, because that’s going to come up soon, too. Notice that the notes don’t point out that the absolute value function cannot equal a negative number. That was there originally, but I took it out, and let students solve a few equations first before we talked about it. I was hoping they’d realize themselves, but it did take a little bit of prompting for them to realize that something like x – 2 = -3 has no solution without having to go through all the steps.
In any case, it show the value of checking the solutions of an equation. In case you were wondering, it is possible to get an absolute value equation that has one legitimate solution and one extraneous solution. Try something like x – 2 = 2x. Our very first skill in Algebra 2 this year was this: IN1: I can simplify radical expressions.
Even though it isn’t particularly related to the rest of the first unit (it’s called “Introductory Algebra Skills”, but it’s really functions and transformations, focusing on linear and absolute value functions), there are a number of reasons I wanted to start with this skill:. In the change over to the new (now one year old) Oklahoma Academic Standards, this content migrated from Algebra 2 to Algebra 1. Meaning my students (who mostly took Algebra 1 two years ago) missed out. So, starting with this is one way of bridging the gaps between the two subjects and the two sets of standards. To a certain extent, this topic stands on its own, so I saw it as a way to get into our course quickly and let my kids start to get the feel of the rapid pace required in Algebra 2. The skill is not particularly difficult, assuming students have a strong grasp already of concepts like radicals, exponents and prime factors. This way, I get to quickly evaluate their understanding of these concepts, and hopefully rectify anywhere they’ve gone astray.
Within the next few weeks, we’ll be graphing functions such as y = x² – 8. I would like for them to give me the x-intercepts as ±2√2. I know that writing out all the factors individually isn’t the fastest method, but I’m a strong believer in the idea that we. In this case, there are a lot of shortcuts, but I’m consciously not teaching them explicitly. I’m certainly dropping a lot of hints that they exist. But if a student really understands the principles here, they’ll be able to find those shortcuts themselves. If a student isn’t able to find those shortcuts, that tells me they still need to develop their understanding of radicals until they can.
There are two key reasons why I think this method is solid, despite its slowness. Firstly, it always works for this type of problem, no matter how many factors the number has, or how many variables we throw under the radical. And secondly, it exposes what’s happening underneath all those strange mathematical symbols. Radicals remove repeated multiplications (or “exponents” as we like to call them).
I want my students to see that repeated multiplication in their mind any time they see an exponent, even if they haven’t written it out. I feel like this second page could be improved a bit. I state the “rules” for adding and subtracting radicals, but there’s not much in the way of justifying why these rules exist. Our class discussion did tease this out a bit more. But I think in future I want to put more emphasis about why addition and subtraction are possible to simplify in some situations but not others. These are my thoughts right at this moment. We can simplify when we add and subtract between things we know the relative size of.
For instance, we know 3 x and 2 x are respectively 3 and 2 times the size of x, regardless of whatever x happens to be. So we can add them and get 5 x. But we can’t add 3 x and 2 y, because we don’t know how x and y relate to each other. (If we happen to actually know how they relate to each other, it turns out there is a way to add them.) Same thing with √2 and √5, or ³√2. We don’t know how they relate. We could always express them as decimals, but that’s the thing we’re trying to avoid so we can maintain an exact value (and that’s trivial with a calculator anyway, and ∴ boring). 3√5 and 2√5 are related, on the other hand, so we can add them and get 5√5.
On the inside of each of these foldables is a blank grid. These are spaces for students to write practice questions in. For this sort of thing, I usually write a few questions on the board for them to fill in here. I like to make them up on the spot, because it lets me gauge how the group is going and adjust the examples I think they need to see. (I’ll admit, this does sometimes backfire as I’m standing at the board, and my mind goes blank.) I don’t typically give them enough questions to fill the whole page, but I encourage them to copy in any other practice questions they want to keep as examples, off of worksheets or wherever else. I like to remind them that their INB is their only reference they have access to on quizzes, so this is good motivation for some of them. This last week saw my Geometry classes finish off our introductory Reasoning and Logic unit, which means we’re ready to go with setting up the basic building blocks of geometry: the Undefined Terms.
I took similar notes last year, but they were constrained to a table on half a letter sheet. This year, I redesigned it to give us a bit more space. My students questioned why we have terms that are undefined, especially after we went over the importance of good definitions in our last unit. I reminded them that definitions use existing terms to define new terms, but that can’t happen unless we have these few terms to build everything else on top of. (Is this a good explanation? Let me know if you know of a better reason to justify the undefined terms.) Next was our first set of postulates and definitions for the year. A change from last year is that these postulates are glued directly onto a notebook page, rather than folded inside a foldable.
This is due to a decision I’ve made this year: all postulates, theorems and definitions will be visible immediately on the page they’re on. Examples, proofs and other content can be hidden in foldables. But if I’m going to expect students to look up certain parts of their notebooks frequently, I should make those parts easy to find. Before we wrote these down, I did a little activity to get my students thinking about why these are true.
I drew two points on the dry-erase board. I didn’t get any photos of this, so I’m re-enacting these on my computer. Then I asked if any volunteers could draw a line through them. That went well enough: I asked if they could do this wherever I put the points. The consensus was that they could. So far, so good. Then I asked if anyone could draw a different line that also went through the two points.
Some kids started saying yes, but then took that back once they realized they didn’t know how to do it. One even got as far as standing at the board with a marker, before handing it back to me and saying it couldn’t be done. My plan had worked as I’d hoped. The class had figured out Postulate 1 without me having to tell them what it was.
After we had written Postulate 1 down, I set my next challenge. Draw two lines that intersect at one point. No-one wanted to stand up to do this, because they thought it might be another trick question.
But eventually, I coaxed one student to the board, who drew something like this: Then I asked for two lines that didn’t intersect at all. I heard a student say the word “parallel”, so I handed her the marker: Then I asked if anyone could draw two lines that intersected twice. But they knew my game by this point, and let me know it couldn’t be done.
So it was time to write Postulate 2. We didn’t get through the rest of the notes in this lesson, but I’ve written them up in my notebook anyway. If you want to download these, you can do so here:. Undefined Terms. Points Lines and Planes: Postulates and Definitions. Let’s cut to the chase.
Here are my units with SBG skills (and alignment to the ) for both Geometry and Algebra 2:. Last year was my first year teaching under the American system, with brand new standards as well. There were some parts of my courses I was happy with, but a lot of things I’m changing this year. I’m pretty happy with how.
I knew pretty much from the moment I was hired that I was going to be teaching it, so I had a lot of time to think about how I was going to arrange things. The biggest change this year is moving Trigonometry from the end of the year. I realized as I went through other units that it would have been useful to have kids knowing how to use right-triangle trig to solve problems, especially ones involving area. I’ve also scrapped the introductory unit, which was mostly some Algebra 1 review and the Pythagorean Theorem. Pythagoras is joining the trig unit now, and I’ll review things like solving linear equations as the need arises. Algebra 2 is changing a lot., my first non-introductory unit was Quadratics.
I found the classes getting bogged down, not making a huge amount of progress. Having to cover both graphing as well as factoring and all the algebraic manipulation that goes along with it got to be a bit too much for my kids. I never really felt like we’d built a solid foundational context for the rest of the course to rest on. This year, the start of the course is going to focus on functions, transformations and inverses. For quadratics that means only dealing with vertex form, as well as showing the relationship to square roots.
We’ll cover all the functions that way, before coming back to all the other algebra we missed along the way. So we’ll cover quadratics again, including all the factoring and solving stuff. While it’s not proper spiraling, I guess it’s sort of a slow spiral.
I’m also teaching Statistics this year, but I won’t be using SBG for it. I feel like I need to learn a bit more about how a standalone stats class works before I attempt that.
Last year I for my Arc planner. I was really pleased with how they turned out and thought they looked really nice. And then I didn’t really use them. There was much more space than I ever really needed, and having multiple levels of pages (monthly and weekly views) meant I never really knew where to put anything. I really want to be the type of teacher to make constant use of my planner.
I’m hoping that I’ve found a layout that actually suits the way I approach my planning. I like having a broad view of a lot of days, but a monthly page doesn’t really help. Because the cycles of school don’t really occur in months, they occur in weeks. But one week to a page doesn’t show enough in my personal opinion. So I created a design that shows three weeks to a page.
I usually create this sort of thing in Publisher or Word, but this one is Excel, using formulas to set all the dates. Download: All the values reference the date in cell A2. If you want to change the starting point of the calendar, change that value (type the full date, not just the day). If you want, say, two weeks to a page, make the columns wider. The font is, but feel free to change that if you want. A couple of months ago a tool I created for sketching graph of parabolas. I called it the.
I don’t know why. It made sense at the time. Anyway, I wasn’t satisfied with it. It has a lot of limitations – mainly, it can only sketch parabolas.
Also, the code behind it is a mess. I thought I could do a better job, and thought it’d be much more useful if it could handle other types of functions.
I spent a few days working on a replacement. Then, and I forgot about it. Then I remembered it today. So, here it is! Introducing the. I know it’s a much more boring name than Parabolator, but I guess my desire to be accurate won out over my desire to be silly this time. For anyone who’s interested, I’m using Vue.js for the control interface, D3.js for the actual graph, and Lodash for something?
Breakbot baby i'm yours. I guess this is why you should post about something while you still remember how you made it in the first place. There’s a new version now, with more functions! Yesterday was the last day of our school year, so it’s finally time to relax! And by relax, I mean write code. I was thinking about the tasks I want to set for next year, and wanted to find a tool to help create sketches of graphs.
Not plots of graphs: there’s for that. No, I mean a bare sketch that shows only the most important points. It doesn’t need to precise, but it does need to be clear, and easy to copy. I searched for a while, but couldn’t find anything that was really what I wanted. There are plenty of tools that can do the job, but not without a bunch of messing around first. So I decided to write my own.
Introducing: the. To be honest, the code behind it is kind of a mess, and it’s extremely limited, but it works. Mess around with it yourself to see what it does. Basically, it draws a parabola based on the location of the vertex and one other point.
The vertex and the “second point” can be dragged wherever to set the parabola’s position, while the “third point” will position itself on the existing parabola when dragged. The axes can be moved by dragging the whole sketch.
Each of the points can be toggled invisible, have labels added, and can be “locked” to the axes. When you’re done, click the download button to save your graph as a SVG file.
To be clear, this is not intended to be a learning tool, and the target audience is not students. I made this purely to help myself create graphs for assignments, and I’m sticking it online because I figure other teachers might find a use for it as well. The use case I see for this is the rapid creation of a graph that can put into an assignment or quiz paper.
It saves as a vector image, so it won’t create big ugly pixels when printed as can happen when a graph is created from a screenshot. One thing I happily discovered today is that SVG files can be directly inserted into a Word document. I’m not going to promise it works perfectly.
Prime Factorization Of 72
I’ve really only tested it with Chrome, so use that if you want the best chance of it working properly. I did also have success in Firefox, but Microsoft Edge has problems with the download feature.
The most obvious drawback to the whole thing is that it only does quadratics. I do want to modify it to support other types of functions, but I’ll leave that for another day. This is just a hobby project, so I’m not sure if I’ll spend much more time on it.
That said, I do have some ideas about what I want to do (especially with adding other functions.) If you’ve got any suggestions, I’d love to hear them. We have one week to go, which means one thing. Okay, it really means a lot of things, but I’m thinking of one thing in particular. Certain students are just realizing what I’ve been trying to tell them all year. Their grade is not high enough and they’re going to have to retake a whole bunch of quizzes before the end of the year if they want to pass. Let’s try and make this a bit more positive.
There’s also a large contingent of students trying to turn Cs into Bs, Bs into As, and even some trying to turn 99% into 100%. Whichever way you look at it, one result is that I have to spend a lot of time with my gradebook, entering quiz scores from random times throughout semester 2, and fielding requests from students to know their grade. The software my district uses doesn’t make this the easiest thing to do. It separates each “Nine Weeks” and makes switching between them annoying, taking a few seconds of loading time and completely resetting the view I had open just before.
Throw in that the same thing happens if I want to enter attendance, and that adds up to a lot of wasted time. My solution to date has been to open multiple web browser tabs with a different view in each.
But that makes my browser cluttered and remembering which tab is which among all my other tabs becomes difficult. Not to mention, the address bar and tabs take up valuable space for seeing students and their grades. I’ve come up with a solution. Google Chrome has a feature that can turn any webpage into a standalone web application, which is displayed as a separate window with a title bar and nothing else.
It appears as a separate app on the taskbar (in Windows at least), which means it doesn’t get mixed up with the rest of my random web browsing. The software my district uses is Wengage, but this applies equally to any gradebook you can access through Chrome (I haven’t tried this with other browsers, but they might do something similar.) To do this, navigate to the page you want to make an app in Chrome.
Click the “three dots” button (I’m sure Google give that a proper name) and select More tools, then Add to desktop This will put an icon for your new app on your desktop (unsurprisingly). Double click that icon to open the app! If you want, you can find the option to “pin” the taskbar icon (keep it there even when the app is closed) by right clicking it.
To be honest, it really is just a chrome tab that looks a bit different, but that’s exactly what I wanted. By appearing as a separate window, it’s out of the way but easily accessible. If you want multiple windows (say, one for grades and one for attendance) hold the shift key while you click the taskbar icon. (Useful tip: this works for almost all Windows programs.) Is this going to revolutionize the way I manage grading?
No, not even slightly. But it has made something I find annoying into something slightly less annoying. Which, to be honest, is exactly what I need as a teacher sometimes.
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