What are some good programmable barcode scanners? - barcode-scanner

Essentially, I'm looking for a 1D bar-code scanner that I can program, either through provided software or some sort of programming language, that will read a bar-code and format the resulting string.
I have already tried the Datalogic Gryphon GD 4130 scanner and it didn't work well with what we needed it to do, and I thought the software they provided was hard to use.
Price isn't an issue either. So any recommendations would be great.

The Honeywell Voyager 9520/40 line worked well for me. The scanner itself was easily programmable by scanning "program barcodes" that they provided.
But I also needed my program to be able to detect barcode scans even if it wasn't the "active" window. And I did not want to create a global keyboard hook to check if any keyboard input was actually a barcode scan.
I found that Honeywell offered free drivers to convert this scanner's output into "serial port" input on the pc - though it was a USB scanner. This was good for programming because it's a cinch to read serial port data in most programming languages, and it would have been rough for me to create some native code to read USB port data.
When researching this I found that most scanners actually had the capability to emulate serial port input so I would recommend that you look out for that feature if you want your program to be able to detect scans without having to get the focus first.
I answered a similar question with some examples here.

The Symbol line of scanners work well and are programmable. We use Model: LS2208. You can program it via barcodes or with free software that can be downloaded from their site. After creating the program you can then save it and/or print it as a sheet of barcodes that can be scanned to reprogram the unit other other units.

Related

Is it possible to extract antenna's radio signal (analog) input samples with RFID FX7500?

I need to do some NON-STANDARD signal processing operations with an RFID-reader, so I'd like to know if it is possible to extract antenna's individual analog (actually digital samples right after ADC) input signal samples with Motorola FX7500 (if you know how this works on FX7400 or FX9500, please do tell, could be helpful). Samples would be processed in a JAVA-based host computer program.
What I've already tried:
Investigating Motorola's own RFID3 API's possibilities, it doesn't go deep enough to actually get in touch with input analog signal samples.
Using LLRP to its full extent, it doesn't allow analog signal sample access either. RFsurvey-functionality would have been helpful to some extent, but FX7500 doesn't support it either.
Accessing RFID-reader's linux terminal, trying to find the driver function(s), that could listen the input sample stream. If current input sample(s) could be extracted from the input stream, I could (in theory) make a script, that would save a few of those sample values in a txt-file in the host computer during a tag inventory round. My linux skills are kinda bad, hence I ask this question.
The only realistic way to solution seems to be via linux terminal, so if you folks have any ideas about that (where to look and what to do), please advise!
Contents of reader:
rfidadm#FX7500abcdef:/$ ls -1
apps
bin
dev
etc
home
include
lib
linuxrc
media
mnt
platform
proc
readerconfig
run
sbin
sys
tmp
usr
var
I cannot completely rule that out, but it's highly unlikely you can get the raw signal digitized; the devices you're looking at aren't really software defined radio devices, typically.
"speaking" RFID physically is a bit different from "usual" wireless communication: The reader doesn't only observe the energy transmitted from the tag, but more importantly the fluctuations of energy extracted from the near field of the reader's antenna coil. Hence, you don't actually have a baseband of RF bandpass signal, but hardware-specific modulations of transmitted (and inversely, antenna-reflected) energy. Demodulation is hence usually done in specialized hardware.
However, do not fret: It's totally possible to build a software defined RFID reader. There have been several approaches to that, but personally, I trust these based on Ettus USRPs and/or GNU Radio best. Look through the results IEEExplore gives you, eg. this search.
Most probably this is not possible with the Motorola readers. What you can do, is use one of the RFID chipsets available on the market: either the AMS RFID IC's, or the Impinj RFID IC's. As far as I know, both IC's support retrieving the digital samples that are received. They also have a development kit to test-drive the IC's.

programmable barcode scanner

Are there programmable barcode readers which I can put program in it. With that program I can tell the reader what are the valid codes. So the reader will refuse to read invalid codes.
Or, with that program, I can encrypt the codes it read.
And, can I use Java to make the program?
There are various types of bar code readers from hand held scanners to counter top scanners to scanner attachments for mobile computers. Most use a USB connection though some use a Serial Port connection. Some are attached to a portable device such as a tablet and some such as a hand held scanner are plugged in. Some hand held bar code readers can also be used as a standing scanner which stands on the counter and do not have to be held.
The two major types of bar codes that I have seen are the standard bar code with the vertical lines of varying widths - see also bar code types from GS1.org - and the QR code from Denso Wave. Commercial point of sale scanners such as counter top or hand held scanners are designed for standard bar code with some also offering the ability to read QR codes. However not all hand held scanners can read QR codes.
Normally the bar code reader will scan the bar code and generate a text string which is then processed by some other device such as a point of sale terminal. I have not seen a bar code scanner that will allow a Java program or similar programatic changes. However there are kiosk type or small devices with a built in scanner which are programmable. See this selection from Symbol.
Bar code readers with a USB connection typically have two ways to configure the drivers, as a HID type of USB device or as a wedge keyboard type of device. The wedge keyboard type of device is usually easier to interface to because it is the same as just reading text from keyboard entry. When using wedge keyboard type of interface, you will typically program the bar code scanner to generate a guard character so that when that character comes into your application you know that it is text generated by the bar code scanner and not from someone typing.
Some types of scanners will have an OLE for Retail POS OPOS Service Object that can be used with an OPOS Control Object. This approach provides device independence for your software since you would write your application to use the OPOS Control Object interface which solves a number of interface issues such as talking to the device using the HID USB interface. However OPOS is a COM type of interface which may be difficult with the Java programming language. Search for information on UnifiedPOS to find your way to the latest standards.
Hand held scanners will have factory settings out of the box and these settings may not be suitable for your application. The hand held scanners I have used can be programmed and their settings changed by a procedure in which special scan codes are scanned in a particular sequence. Normally the user manual for the particular scanner will have an appendix or two with the documentation as to what settings can be changed, the procedure or steps to use to make changes, and the bar codes to be scanned for the procedure steps. You will probably need to search the manufacturer's web site for the appropriate manual.
For instance the Motorola LS2208 Product Reference Guide contains various sections on setting up that hand held scanner for various environments and scanner applications. The following screen shot from a page of the guide shows the bar codes used to set up the device for USB interface.
Another option would be to have an application on a phone that uses a phone camera as the bar code scanner. However it appears that most cameras are not good for standard bar codes.
Most scanners for retail systems are fairly complex with lasers for the actual scanning. I have used several different types with point of sale application and they are all fairly easy to use. You can change the settings by entering commands using a set of bar codes which are part of the documentation. These settings are for such things as bar code symbology, prefix characters, suffix characters (prefix and suffix characters are used with wedge keyboard type of interface).
See this forum discussion on using a camera for standard bar codes.
See also this web page on Android bar code scanning.

Using a piano keyboard as a computer keyboard [closed]

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I have RSI problems and have tried 30 different computer keyboards which all caused me pain. Playing piano does not cause me pain. I have played piano for around 20 years without any pain issues. I would like to know if there is a way to capture MIDI from a MIDI keyboard and output keyboard strokes. I know nothing at all about MIDI but I would like some guidance on how to convert this signal into a keystroke.
I haven't done any MIDI programming in years, but your fundamental idea is very sound (no pun).
MIDI is a stream of "events" (or "messages"), two of the most fundamental being "note on" and "note off" which carry with them the note number (0 = C five octaves below middle C, through 127 = G five octaves above the G above middle C, in semi-tones). These events carry a "velocity" number on keyboards that are velocity sensitive ("touch sensitive"), with a force of (you guessed it) between 0 and 127.
Between velocity, chording, and the pedals, I'd think you could come up with quite a good "typing" interface for the piano keyboard. Chording in particular could be a very powerful technique — as I mentioned in the comments, it's why rank-and-file stenographers can use a stenotype machine to keep up with people talking for hours in a row, when even top-flight typists wouldn't be able to for any length of time via normal typewriter-style keyboards. As with machine stenography, you'd need a "dictionary" of the meanings of chords and sequences of chords. (Can you tell I used to work in the software side of machine stenography?)
To do this, the fundamental pieces are:
Receiving MIDI input. Don't try to do this yourself, use a library. Edit: Apparently, the Java Sound API supports MIDI, including receiving events from MIDI controllers. Cool. This page may also be useful.
Converting that data into the keystrokes you want to send, e.g. via the dictionary I mentioned above.
Outputting the keystrokes to the computer.
To be most broadly-compatible with software, you'd have to write this as a keyboard device driver. This is a plug-in to the operating system that serves as a source for keyboard events, talking to the underlying hardware (in your case, the piano keyboard). For Windows and Linux, you're probably going to want to use C for that.
However, since you're just generating keystrokes (not trying to intercept them, which I was trying to do years ago), you may be able to use whatever features the operating system has for sending artificial keystrokes. Windows has an interface for doing that (probably several, the one I'm thinking of is SendInput but I know there's some "journal" interface that does something similar), and I'm sure other operating systems do as well. That may well be sufficient for your purposes — it's where I'd start, because the device driver route is going to be awkward and you'd probably have to use a different language for it than Java. (I'm a big fan of Java, but the interfaces that operating systems use to talk to device drivers tend to be more easily consumed via C and similar.)
Update: More about the "dictionary" of chords to keystrokes:
Basically, the dictionary is a trie (thanks, #Adam) that we search with longest-prefix matching. Details:
In machine stenography, the stenographer writes by pressing multiple keys on the stenotype machine at the same time, then releasing them all. They call this a "stroke" of the keyboard; it's like playing a chord on the piano. Strokes frequently (but not always) correspond to a syllable of spoken language. Like syllables, sometimes one stroke (chord) has meaning all on its own, other times it only has meaning combined with following strokes. (Think "good" vs. "good" followed by "bye"). Although they'll be heavily influenced by the school at which they studied, each stenographer will have their own "dictionary" of what strokes they use to mean what, a dictionary they will continuously hone over the course of their working lives. The dictionary will have entries where the stenographic part ("steno", for short) is one stroke long, or multiple strokes long. Frequently, there will be several entries with the same starting stroke which are differentiated by their length and by the subsequent strokes. For instance (and I won't use real steno here, just placeholders), there may be these entries:
A = alpha
A/B = alphabet
A/B/C = alphabetic
A/C = air conditioning
B = bee
B/C = because
C = sea
D = dog
D/D = Dee Dee
(Those letters aren't meant to be musical notes, just abstract markers.)
Note that A starts multiple entries, and also note that how you translate a C stroke depends on whether you've previously seen an A, a B, or you're starting fresh.
Also note that (although not shown in the very small sample above), there may be multiple ways to "play" the same word or phrase, rather than just one. Stenographers do that to make it easier to flow from a preceding word to the next depending on hand position. There's an obvious analogy to music there, and you could use that to make your typing flow more akin to playing music, in order to both prevent this from negatively affecting your piano playing and to maximize the likelihood of this actually helping with the RSI.
When translating steno into standard text, again we use a "longest-prefix match" search: The translation algorithm starts with the first stroke ever written, and looks for entries starting with that stroke. If there is only one entry, and it's one stroke long, then we can reliably say "that's the entry to use", output the corresponding text, and then start fresh with the next stroke. But more likely, that stroke starts multiple entries of varying lengths. So we look at the next stroke and see if there are entries that start with those two strokes in order; and so on until we get a match.
So with the dictionary above, suppose we saw this sequence:
A C B B C A B C A B D
Here's how we'd translate it:
A is the start of three entries of varying lengths; look at next stroke: C
A/C matches only one entry; output "air conditioning" and start fresh with next stroke: B
B starts two entries; look at next stroke: B
B/B doesn't start anything; take the longest previous match (B) and output that ("bee")
Having output B = "bee", we still have a B stroke in our buffer. It starts two entries, so look at the next stroke: C
B/C matches one entry; output "because" and start fresh with the next stroke: A
A starts three entries; look at the next stroke: B
A/B starts two entries; look at the next stroke: C
A/B/C only matches one entry; output "alphabetic" and start fresh with the next stroke: A
A starts three entries; look at next stroke: B
A/B starts two entries; look at next stroke: D
A/B/D doesn't match anything, so take the longest previous match (A/B) and use it to output "alphabet". That leaves us with D still in the buffer.
D starts two entries, so we would normally look at the next stroke — but we've processed all the strokes, so consider it in isolation. In isolation, it translates as "dog" so output that.
Aspects of the above to note:
You have a buffer of strokes you've read but haven't translated yet.
You always want to match the most strokes against a single entry that you can. A/B should be translated as "alphabet", not "alpha" and "bee".
(Not shown above) You may well have sequences of strokes that you can't translate, because they don't match anything in the dictionary. (Steno people use the noun "untranslate" -- e.g., with our dictionary, the strokes E would be an "untranslate".)
(Not shown above) Some theories of steno allow the same set of strokes to mean more than one thing, based on a broader context. Steno people call these "conflicts". You probably want to disallow them in your project, and in fact when steno used to be translated manually by the stenographer, conflicts were fine because they'd know just by where in the sentence they were what the right choice was, but with the rise of machine translation, conflict-free theories of steno arose specifically to avoid having to go through the resulting translated text and "fix" conflicts.
Translating in real time (which you'd be doing) means that if you receive a partial match, you'll want to hold onto it while waiting for the next chord — but probably only up to a timeout, at which point you'd translate what you have in the buffer as best you can. (Or maybe you don't want a timeout; it's your call.)
Probably best to have a stroke that says "disregard the previous stroke"
Probably best to have a stroke that says "completely clear the buffer without outputting anything"
Consider doing something in hardware that emulates a usb (or ps/2?) keyboard. You will no longer be dependent on a specific OS, or specific OS API. A hardware solution will stand the test of time. Don't be stuck using an old API in Windows 7 when everyone else is running Windows 11! Arduino is pretty easy to learn.
Arduino MIDI hardware is available off of the shelf
Arduinos have been used to emulate keyboard devices
There is a ton of info and help out there for Arduino. It is a hardware hacking platform built for newbies. It will only get bigger now that Google is pushing Arduino.
EDIT: Virtual USB Keyboard software and hardware
It sounds to me like you're looking less for advice on how to build this yourself and more asking what resources are already out there to accomplish what you want. Depending on your OS, there are many ways to accomplish this without having to write your own program from scratch:
MIDI Stroke
Free. For Mac OS X 10.3 and up. This one specifically comes with "the ability to use any MIDI keyboard as a full blown computer keyboard replacement."
Bome's MIDI Translator
Free/Postcardware (it's a bit odd). For Windows 2000 and up, and Mac OS X. It initially appears to be more geared towards AutoHotkey-type usage, but on further looking I think it could do what you want nicely.
Max and aka.keyboard
Free. For Mac OS X. Not exactly a "ready out of the box" solution, but if you are comfortable with basic device configuration, it shouldn't be too bad.
You can access the hardware with source code samples in .NET in MIDI DotNet.
A complete working sample as sourcecode to create MIDI notes data stream is in VB 5/6-Tipp 0521: MIDI-Töne erzeugen (Visual Basic 6.0, somewhere is .NET version too)
A way to simulate keyboard strokes is in VB 5/6-Tipp 0155: Tastaturereignisse simulieren (Visual Basic 6.0, somewhere is .NET version too)
And recognize keystrokes is describedin Tipp-Upload: VB.NET 0266: Globaler KeyHook.
Then, just use a good working matrix for a piano player
On piano and when you're a good player, you can have 10 fingers on the keyboard and if the matrix is usable you can be much more quickly that any computer keyboard user I think. :-)
In that case, if I understand your question right, it should not be a big thing.
I studied piano performance in college and then got into interaction design, programming, and using Vim, so I have actually spent a lot of time prototyping things like this.
You can get this working pretty quick in Linux by using the graphical programming language for multimedia artists, "Pure Data," along with the x11key external by Alex Andre.
On Mac, you can use MidiStroke. I believe a method on Windows involved the MidiOx and AutoHotKey tools. At another time I had a version going using the Java plugin for Max/MSP. I believe Patrice Colet made a windows external for Pure Data that worked as well, but I can't seem to locate it anymore. Also, there's an external for MaxMSP that can do this on Windows. Finally, the non-free but awesome Osculator can do what you want - see the features page.
When I got it working, I never stuck with it, because I couldn't stop tooling with the layout. It was cool just having my monitor on my electric keyboard, though! Good luck.
About MIDI
You stated that you "know nothing at all about MIDI". MIDI technology is fairly straight-forward once you grasp it, but it can be confusing at the outset. One of the resources that has been tremendously helpful for me in understanding the foundations for MIDI (which are certainly necessary if you want to program MIDI interactions), is a book called MIDI for the Technophobe. It's an easy book to read and is very helpful.
Pure Data & Max
In my experience developing interactive multimedia, there are two very similar programs I have encountered that facilitate connecting and mapping signals/inputs from any device.
These are Max for a Mac environment and Pure Data for a PC environment. Both have a plethora of online documentation and YouTube tutorials. The video Max/MSP Tutorial 1 - using your computer keyboard as midikeyboard (ableton style) demonstrates a program built in Max that maps a computer keyboard to a MIDI keyboard's inputs (which is basically the exact opposite of what you are trying to do). You could get your intended results by using the same pattern, but reversing the signals/mappings.
AutoHotKey
AutoHotKey is a free open source utility for Windows that allows you to remap keys and buttons on your devices to macros. It natively supports QWERTY keyboards, joysticks and mouse macros.
However, I was able to find an implementation supporting the specific mapping you are looking for. These two threads explain the process:
MIDI IN support in AutoHotkey , the discussion of the use case. The author was looking for a program that could detect MIDI IN input and translate that to keypresses.
MIDI input library , the solution to the author's problem and the posted code/patch to AutoHotKey which actually implements your intended result.
Basically, it looks like AutoHotKey, along with this user's custom patch, will provide exactly what you need to create a mapping from a MIDI keyboard to a QWERTY keyboard's input signal. All you would have to do is install, configure and define your mappings.
Anything else?
Some of the other answers have given you much more extensive information on MIDI and MIDI programming, in general, but as your post states that doesn't seem to be quite what you are looking for. I would like to help you more if possible, but it would be easier if you could be more specific about the type of information you are looking for. For instance, are you more interested in how to convert a MIDI keyboard's input signals to a QWERTY keyboard's signals, or is your primary interest finding an out of the box solution to your specific problem? What are you looking for that has not yet been addressed?
You could hack your own USB keyboard pretty quickly using a Teenys micro controller.
In fact, they have example code for how to make a USB keyboard.
You could approach this two ways:
Get an old piano and wire up switches directly to the teensy
Add the additional logic to connect to the MIDI port and necessary decoding.
Actually, I worked on this a while ago, trying to capture Rock Band drum inputs into my computer (making a little Java homemade drum emulator) Anyway, I asked a question on here about that, Time delay problem (there is polling code in there, along with what I was attempting to do.). And if I can find my program I can give you the code, it uses a third-party API (JInput).
Good luck either way.
Try Bome's MIDI translator.
It works cross platform, can convert any MIDI input to a keystoke easily, quick to setup and configure, plus it's free for personal use.
There is a tutorial, Quick Tip: MIDI Translation – MIDI to Keystrokes, of how to easily set it up:
Basically, there are infinite possibilities of what you can do, including chording and modifier keys. I use it for my live audio rig to control my DAW using my piano and have never had an issue.
In Java, you can use JMF (Java Media framework) to convert MIDI signals.
Basic of keyboard design is easy to use, that is, the user interface; and place frequently used charcter/symbol handy.
The sample code and API in Java Sound Resources: Examples: Digital Signal Processing (DSP) help to understand how to process the signal.
Some more references:
Processing Audio with Controls
Digital Audio Signal Processing, 2nd Edition
A good library in .NET with full midi support (BASS), go to http://www.un4seen.com.
And for the other part, translating keyboard midi notes to keys and more, I would go for AutoItX, the ActiveX/COM and DLL interface to autoIt. Info and download, go to http://www.autoitscript.com/site/autoit/
No need to write keyboard driver.
There is a program called GlovePIE. You can program it in a simple scripting language, and I believe it supports MIDI. I'm not sure if this fits under the "Java" category, but still, it is a great program. I've used it to control robots using PS3 controllers. It's very powerful.
Many keyboards have a serial port (RS-232) connector to send MIDI signals to the computer. I use a program called Girder to convert serial port communication into keyboard strokes.
Girder has a "mapping" feature that lets you map each key, one by one, to the corresponding keystroke.
This might be the simple solution you're looking for!
Just learn stenography!
It's clear from all the discussion on your part. You don't want to re-invent any wheels, from a technical standpoint. But once you have a connection made (what this question is asking) and up and working, you still have most of the work ahead of you: You have to train your brain. You also have to invent the cleverest, most efficient way to do that - a design issue totally out of the rhealm of computer techies. You or any of us would fall short.
Fortunately, the problem has been solved and honed though centuries of maturing...
Learn stenography!
Yes, this will set you back some jack. But what are hundreds of hours of your own time worth, with at the end, a less favorable result? Besides, the stenography Wikipedia article says, 'it looks more like a piano keyboard'.
Unless, of course, you want to have a sideshow effect going. I would have to admit, I never thought of this possibility, it it would be really entertaining to see somebody bust out a text from a piano keyboard!
You could start with a USB keyboard with touchpad (or a pointing stick would be more ergonomic?), use Plover to translate it (I'm sure it can be configured to let the non-letter keys retain their functionality as they are critical for programming), or, follow the thread Re: Plover keyboard to roll your own USB stenography keyboard, or, buy a stenotype.
Good luck!
Take a look at MAME arcade gaming. They have built hardware devices to allow input from any number of different items. The iPac, for example, converts signals from input devices into USB that the computer can then use to emulate keys. You could use any combination of input devices arranged any way that seems comfortable with no crazy programming logic required--because the software to interpret input is already done and well tested.
I've seen flight simulator cockpit inputs, custom kiosks, and voting systems built in this method.....and the price is right!
To solve this you will need a few things:
A way to capture MIDI data from your keyboard. Depending upon the interface: MIDI interface (classic) or USB MIDI interface (modern) the most likely interface is to a computer as it provides the most options. USB host microcontrollers are not as simple as just using a computer.
A scheme to convert MIDI data into keystrokes. Like one user pointed out, chords are the way to go as the number of keys will not be dependent upon the number of piano keys.
A way to inject a key into the operating system. This will require a low-level driver to be accurate. I have played around with applications that inject keyboard and mouse data into applications in Windows 7, and it can be flaky and depend upon whether an application is currently in focus. This is hardest part of the interface. What may work is to create a HID USB keyboard microcontroller that also has a serial interface.
The serial interface would create a virtual serial port. The software that reads the MIDI data and produces the keystrokes could send a serial message to the virtual serial port. The microcontroller would send a keystroke so it would look like a standard keyboard input. This would allow interfacing both MIDI ports and USB MIDI keyboards.
Hmmm, with this type of interface you could also simulate a mouse and use some piano keys setup for the mouse axis and buttons. The pressure could be used to determine mouse pointer velocity. So you could eliminate the mouse as well. Another benefit of this approach is any type of input device you connect could talk to the virtual serial port to produce keyboard and mouse events. So if you wanted to add other hardware such as drum pedals or a joystick it would be a matter of adjusting the program that talks to the serial interface.
Another take on the above is like some posted above to use an Arduino, but also include USB Host Shield from Sparkfun to handle USB based music keyboards. This allows the Arduino to be programmed as a keyboard or keyboard mouse combo in the boot loader chip and allows the device to act a USB host for the USB based music keyboard. Then you are covered for both types. Although, I still think the virtual serial port method is more flexible and would be easier to program in the long run. The Arduino device will be harder to change than a desktop program or service.
There is another possibility:
Chorded one handed keyboards already exist. I have seen videos on them, but you would have to determine if those hurt your hands or not.
It should be fairly easy using something like the .NET DirectSound interface to hook into an MIDI device. You will need to identify your target MIDI device and then get the code to listen in on the incoming messages (there are articles about doing this via Google).
Since you are using the MIDI in as a keyboard there are basically only two MIDI messages that you need to detect, namely note on and note off. The MIDI message is three data bytes specifying the command, the note and the velocity. The note off is just the note number (sometimes 'bad' MIDI stacks send a note on with zero velocity which you also have to expect).
Once you have the messages translating them the keyboard output should be fairly simple from .NET.
There is plenty of advice in the other answers about the technicalities; I just wanted to give you an idea of the actual MIDI messages. Good luck!
You'll get better and happier results (regardless what operating system and/or DAW program you like to use) by playing any external MIDI keyboard as a controller through your sound card. Then route that into your GB software (or whatever) and tone generate the many sounds they have supplied you that way in real-time.
If your sound card does not support MIDI I/O's (ins / outs /thrus), that's not a problem. You can consider researching and investing in an external MIDI table top converter. Many are equipped to further convert MIDI outs to USB 2.0 (by- passing an existing sound card altogether).
For example: it's pretty tough getting "human like" grace note results via a Z and X change key option using a computer keyboard and pencil tool. When, instead, your own fingers can just play that with a MIDI keyboard from its own physical octave register ranges—immediately!
I realize budgetary constraints may be involved. But, some of these seemingly cheap "Casio" type 5 octave keyboards sold at Radio Shack for under $100.00 U.S. Dollars (*or less) is all you would need (plus, some of their on-board sound patches and sequencer modules sound and handle amazingly well for other things too).
RadioShack MIDI keyboard options.
As for external MIDI converters for existing sound cards, I've run some Google searches for you as follows with Mac platforms specifically in mind:
A lot of this external MIDI conversion information may be cumbersome to you at first, so I've broken down things more as "user friendly" for your considerations & budget:
MIDI sound cards
There's nothing wrong with facilitating virtual keyboards as VST's when using DAW. They have their place.
But, you sound like an accomplished keyboardist. So, why not consider the external MIDI conversion / keyboard options I just mentioned for yourself?
Good luck and I hope this gave you some ideas that can and will work for you!
If you don't want to do any programming yourself but just want the problem solved you can just buy a USB-MIDI-keyboard where you can re-assign any key to send a QWERTY keyboard output signal instead of a MIDI-output, for example M-Audio Axiom Pro
This method will work with any OS and any computer that supports standard USB-keyboards since the MIDI-keyboard will identify itself as a standard QWERTY keyboard.
You can use a simple AutoIt script to both read MIDI events, see MIDI Input.
You'll also need MIDI UDF and simulate key presses.
Reading MIDI events should be easy, but different MIDI controllers (instruments) have different features. Try to find out what your MIDI piano can do first, then see how you can best map those features to simulated QWERTY-keyboard presses.
If you want, you could have something on screen or in the tray to help you see what you are doing (that is, for Shift, Ctrl and Alt simulation).
You might take a look at chorded keyboards. They have the advantage that you don't need to write a driver for them before you can use them, and some are similar to the layout of a piano keyboard.
If you know coding in Java, you could use this way:
First, implement a javax.sound.midi.Receiver with a send(..) method that is mapping the 'Note on' events to keystrokes like you want.
You would need to get the MidiMessage's content with its getMessage method and intepret it in your fashion. The meaning of the message bytes can be found in MIDI Messages.
After receiving a 'note on' or 'note off' for a certain keyboard key, you may map that to a key you like by assigning it a constant of the KeyEvent class, something like C#4 -> KeyEvent.VK_A and so on. This key code can then be used by java.awt.Robot's keyPress and keyRelease methods to actually send the keystroke to the OS and thus to other applications.
I agree with Brian O'Dell's answer - if this were my project, I'd do it in hardware. It has the advantage of being platform and hardware independent - your box replaces the need for a MIDI-USB interface and a PC API.
mbed is a fast-prototyping platform that is very easy to learn, and has multiple advantages over Arduino IMHO (online compiler, 512 KB flash, 96 MHz, C++ language). It has a USB keyboard interface and a USB Midi interface pre-written for you.
The community is very friendly and willing to help, and there are a lot of existing projects using both MIDI and USB hid emulation - search Youtube for "mbed MIDI" or similar.
If you use Linux have a take at Footware.
It should be exactly what you're looking for - if you adjust the MIDI pitches to a keymapping of your liking...
I never thought this could be useful for anyone but me ;o)
Try using a microcontroller-based system, like Arduino.
This wouldn't be too tough.
I'm assuming you're on Windows, not sure about that though. I've written a MIDI sequencer, http://pianocheetah.com, in plain old C++, and it lets you use the piano keyboard to run commands. There isn't any reason you couldn't do the same thing to push keys
into the keyboard input stream.
But come on now. You remember how long it took you to learn
the keyboard in the first place, right?
Are you willing to go through that again?
And are you willing to pollute your blessed keyboard with
a bunch of stupid looking key symbols all over it?
You'll need to use at least 26 alpha, 10 numeric, 11 punctuation,
and at least 12 function keys AND their shifted states.
So that's 60 keys plus shifted states.
That'll burn up a full 5 octaves of keys.
You will be doing piano "hops" =all= the time.
Say goodbye to touch typing.
You may save yourself from RSI, but you've created another
different type of nightmare for yourself.
And good luck getting your boss to buy you a MIDI keyboard at work.
If you've learned to truly play piano, you've learned
how to play stress free. Do that on the QWERTY keyboard.
No tension. Start slow.

USB interface barcode scanners

Not exactly a programming question, but close. I'll try my luck anyway.
The keyboard wedge
barcode scanner inserts the
translation device between the reader
and the keyboard. Data sent through a
wedge appears as if it was typed into
the computer, while the keyboard
itself remains fully functional.
Because a computer using a keyboard
wedge can't tell the difference
between data that is entered by a
scanning device, or data that is
entered by keyboard typing, a wedge
can be used to easily add barcode
reading capability to an existing
computer without modifying software
applications.
I'd like to know if all USB interface barcode scanners automatically translate digital signals from a barcode reader into keyboard strokes for a applications just like wedge or is USB different from wedge?
Many thanks
There are all sorts of API to access barcode scanners -- by no means do they all work by making believe they're "the keyboard"!-) For example, here you can find a reasonable summary of possibilities (the classic rs232 approach, the "wedge" one, and USB-interface ones) albeit for a single firm producing them. Depending on what programming you're willing and able to do, your best choice might be any of these approaches, or others yet.

Program for HID USB Scale [closed]

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I'm looking for a program that can read the weight on a USB scale, namely the Pelouze 10lb USB Portable Scale. I thought it would have a virtual COM port driver but instead, it uses HID drivers. I've been searching for a whole month for a program that can help me transfer the reading of the scale to Microsoft Excel. Can someone help me out or point me in the right direction? I am absolutely illiterate to programming. Much gratitude any help given.
I can offer some helpful links.
The scales use the "HID point of sale" USB spec, a link to which can be found in the comments section of the blog post I mention below. I'd link direct, but the spam prevention mechanism prevents me.
There's a blog post on addressing the 25lb version of the scale from C#, here: http://nicholas.piasecki.name/blog/2008/11/reading-a-stamps-com-usb-scale-from-c-sharp/
The comments on that post are helpful - that's where you find the USB spec, there's also a comment showing how to get at the data without using the full HID library.
Good luck with your project!
I wrote some code to read from a Dymo USB scale using Python. It requires libusb and PyUSB.
This code is pretty general; it should work with any HID device that has just one configuration:
import usb.core
import usb.util
VENDOR_ID = 0x0922
PRODUCT_ID = 0x8003
# find the USB device
device = usb.core.find(idVendor=VENDOR_ID,
idProduct=PRODUCT_ID)
# use the first/default configuration
device.set_configuration()
# first endpoint
endpoint = device[0][(0,0)][0]
# read a data packet
attempts = 10
data = None
while data is None and attempts > 0:
try:
data = device.read(endpoint.bEndpointAddress,
endpoint.wMaxPacketSize)
except usb.core.USBError as e:
data = None
if e.args == ('Operation timed out',):
attempts -= 1
continue
print data
For the DYMO M10 scale I'm using, the data packet is a 6-element array like this array('B', [3, 2, 11, 255, 0, 0]).
The last two elements are used to calculate the weight.
In kg mode grams = data[4] + (256 * data[5]), and in pounds/ounces mode ounces = 0.1 * (data[4] + (256 * data[5])).
More info on my blog post.
The first question that you will need to answer is the exact HID use. USB describes a wide family of related protocols. USB HID is a subset, but this still covers a large array of devices. The HID specs defines a 32 bits "usage" identifier supporting up to 4 billion different types of HID devices, although only a fraction of those values have been assigned so far.
The Windows API you'll probably need is Raw Input. Unfortunately, this is not an interface for the programming illiterate.
For USB devices not supported directly by the O/S, you either need to be a programmer, or you need a program supplied by the device vendor. In this case, as it sounds like you're not a programmer, you should contact the manufacturer to see if they can provide any diagnostic or testware programs that could be used to read and capture the scale data. If you're lucky, such a program can be "batched" and it's output redirected, or something like that. Good luck.
Elane sells a line of USB HID scales and also has a Windows program to read the weight. Unfortunately, because of Stamps.com, that program is no longer free. At $15.50, it's not necessarily something I'd want to blindly try, but here it is:
http://www.elane.net/index.php?go=USB_pcsoftware
if you want to play detective this guy's advice might help :
http://nicholas.piasecki.name/blog/2008/11/reading-a-stamps-com-usb-scale-from-c-sharp/
Just ordered a DYMO scale myself so will post findings
http://r.lagserv.net/scalereader.htm
This is great code to get started with for C# and a Dymo scale using HidLibrary.
Just change the vendor ID to match that of your scale.
You can be up and running in a few minutes.
I used it with a Dymo S400.
I wrote my nodejs version and shared the code at https://github.com/PhantomRay/dymo-scale-nodejs.
It is only tested in Windows 10. Also, it has a simple web socket server mode built to it so that any web page can connect to it to read data.
I would assume that output from a USB HID device like this should appear to the USB host exactly as if the input was typed on a keyboard, i.e. on the scale stabilising, the weight would be sent over USB. This is the way most USB barcode scanners work.
If this is the case then the scale should just fire across the weight and it would appear in whatever application was active; Excel if that is where you wanted the input to end up.
However, I've looked over the specs and manual for the scale you specify and, unless I'm looking at the wrong model, although it is powered by USB I don't see any mention of the fact that it also communicates over USB. Do you have a URL or part number?

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