Top Spin 4 Pc Emulator
Simone Alwang
any help with hyper spin would be great . i have hyper spin running on my pc, and only can get my x arcade stick to work with mame. no other emulators at all. please help, i want to map my buttons for the other emulators with my x arcade stick to use for the main hyper spin menu and for games i want to play. just can't figure out how to map them. please help. the only way i even got mame to work with my x arcade stick was the x arcade stick website had a easy button mapping config for hyper spin. i know in hyperhq i have went in there but it seems to just control the main hyper spin menu like scrolling through the wheels, but if i click on a emulator say snes i can open a super mario game, but thats it, can't start a game can't ad a coin , because they aren't mapped. i am a full blown noob to hyper spin guys, sorry!! but pretty good at emulators usually. but hyper spin is on another level
Hi Ken, you will have to configure each emulator you use outside of HS/RL first. For Super Nintendo, there is no "insert coin" as that is not an arcade system. Open your SNES emulator (for me that's snes9x) and look for "input" or "controller" or "options"... maybe "preferences" (every program has there own wording). Then configure what buttons you want to do what.
ok so if i open snes in hyper spin,. where the heck is input or configure or preferences?? i only have the emulator main screen with the wheel showing all the games. there is nothing at the top of the screen or bottom that say input?? do i have to like hit a certain key to bring those options up??? please please please anyone explain how to in hyper spin individually configure each emulator, i see no option for that at all. if i can do that i will be good to go. i just want to map these buttons on my x arcade or xbox 360 controller and i just can't figure it out. thank you for the reply spawk , please keep the coming and anyone else too. remember i am a newb to hyper spin, so bare with me, just please help explain where to configure each emulator for button mapping or settings.!!
ok i get that. config out of hyper spin. well i have hyper spin on a external 2tb hard drive. should i go into that external drive and then open hyper spin, not launch HS but just open it.. and then i see all the loaded emulators, and try and config each emulator from inside there?? i bought a pre installed hard drive, so i did not load all this stuff. thought it was plug and play. please help exactly how to config my x arcade stick on hyper spin emulators. and also how to config a xbox 360 controller to hyper spin?? please if you will explain 100 % clearly like you are explaining to a newb. sorry to bug, just need help configuring my button mapping for each emulator.
Make sure your x-arcade is working by opening notepad and moving the sticks and pressing the buttons. You should change the LEFT ALT, LEFT SHIFT, and LEFT CONTROL keys if they are programmed as inputs eventually because they'll cause problems in some emulators. Don't work about them now. If everything checks out, you're good.
If the control panel is working, get a game running. I always start with NES and Super Marion Brothers because it's easiest, then move on to the next system. Somewhere on that drive should be an emulator folder. Find the one for NES (probably Nestopia or Retro Arch). If it is Retro Arch, I would recommend you use Nestopia instead because it sounds like you're starting from square one, Nestopia will be easier for you. Locate the ROMs folder for NES, the files should be .NES, .ZIP, or .7z.
Open Nestopia. There are input options in the menu (I'm not at my arcade machine so I can't tell you exactly where). Configure the input to use your x-arcade. The x-arcade is seen as a keyboard in Windows. I like to make the bottom left button SELECT, the first button B, the second button A, the fourth button B-Autofire and the fifth button A-Autofire. Also configure full screen and anything else you want while you're in there. Make it run exactly how you eventually want it to run in Hyperspin.
Setup your NES system in Rocketlauncher and launch the game from inside Rocketlauncher. If it works, move on to Hyperspin. If it doesn't, the error message should be clear as to why not. The most likely cause will be ROM naming.
Hi guys, i wanna to quit fuse emulator, how predeterminate emulator for spectrum games. I would try use ZX Spin 07 like predeterminate emulator, but when i tried to run any game, this emulator dont start. I added ZX Spin like emulator predeterminate, but its possible i need command line?
Thank you very much for your help
However I do remember having problems with it at first..if it still doesn't work with the setup below, try deleting the spin.ini from the emulator directory, the ini will be recreated once you run the emulator.
Ok i find the problem. i have deselected retroarch - fuse like prederminated emulator, but in on the games, appears Retroarch like emulator for run the games. If i try to change the emulator, the game run fine. The question is, how i can change all the games to the new emulator?
I made that, but dont work. When i selected one emulator for the game, this game run ok, but when i tried to run another game, appear the same problem, not run the selected emulator also previous. I have to change manually the emulator on all spectrum games? thats its not normal. I should change the emulator for all the games at same time.
Finding the solution to a large category of optimization problems, known as the NP-hard class, requires an exponentially increasing solution time using conventional computers. Lately, there has been intense efforts to develop alternative computational methods capable of addressing such tasks. In this regard, spin Hamiltonians, which originally arose in describing exchange interactions in magnetic materials, have recently been pursued as a powerful computational tool. Along these lines, it has been shown that solving NP-hard problems can be effectively mapped into finding the ground state of certain types of classical spin models. Here, we show that arrays of metallic nanolasers provide an ultra-compact, on-chip platform capable of implementing spin models, including the classical Ising and XY Hamiltonians. Various regimes of behavior including ferromagnetic, antiferromagnetic, as well as geometric frustration are observed in these structures. Our work paves the way towards nanoscale spin-emulators that enable efficient modeling of large-scale complex networks.
Lately, it has been shown that the solution of an NP-hard problem maps to finding the ground state of certain types of spin Hamiltonians with polynomial overhead [6], [7], [8]. Such spin Hamiltonians naturally arise in certain magnetic materials, representing the respective interactions among magnetic moments. In most cases, however, these magnetic materials lack the required versatility to be used for computational optimization. To address this issue, ultracold atoms in optical lattices have been employed to emulate magnetic spins [9], [10], [11], [12], [13] and most recently, active photonic platforms have been pursued as a viable means for experimental realization of spin Hamiltonians. In this regard, unlike passive implementations, such optical systems can identify the ground state of the corresponding Hamiltonian by their natural tendency to operate in the global minimum loss. Thus far, spin exchange interactions including classical Ising or XY Hamiltonians have been demonstrated in optical parametric oscillators (OPOs) [14], [15], [16], polaritonic simulators [17], [18], [19], degenerate laser cavities [20], [21], multicore fiber lasers [22], and spatial light modulators [23]. At this point, one may ask whether it is possible to exploit the vectorial degrees of freedom of light [24] in nanoscale structures in order to develop ultracompact photonic spin simulators. If so, such on-chip nanophotonic arrangements could potentially enable large-scale optical emulators to address NP-hard optimization tasks in a scalable manner.
A schematic picture of an array of N=5 metallic nanodisk lasers used in this study. The green arrows depict the orientation of the pseudospins. The inset shows lasing mode of a five-element nanodisk laser array as obtained from FEM simulations. The rotation of the local resonant modes is illustrated with dashed arrows, indicating the pseudospins.
Equations (3) and (4) clearly show that the total dissipated power in the nanolaser array described here depends on the relative orientation of the vectorial EM modes in the individual cavity elements (ϕj). In other words, one can assign a pseudospin to the field distribution in each individual cavity as depicted in Figure 1. The overall loss endured by each collective supermode of the system is then effectively determined by the orientation of these pseudospins. In this regard, the above loss functions represent the spin Hamiltonians for the particular modes of interest with various azimuthal orders. Once gain exceeds the lasing threshold of the system, the resulting lasing supermode satisfies the minimum conditions for the loss functions described above. Therefore, Eqs. (3) and (4) play the role of an equivalent energy landscape function which is minimized by the structure when it starts to lase. This can be formally established by defining the following equivalent Hamiltonian associated with the TE and TM family of modes in the metallic nanolaser arrays considered here:
Realizing the Ising Hamiltonian in nanolasers. (A) Ising spins with FM exchange interaction implemented by the TE01 modes in coaxial nanolasers. The black arrows show the direction of the azimuthal electric fields. (B) A three-element Ising Hamiltonian with AF couplings realized using a TM01 resonant mode of the nanodisk lasers. One of the possible degenerate ground states is presented here. The white arrows show the direction of the azimuthal magnetic fields within the resonators.
Ferromagnetic and antiferromagnetic XY Hamiltonians in various geometries. (A) A four-element nanodisk laser where a TE22 mode is dominantly lasing. The corresponding ground state is obtained from FEM simulations. (B) Square lattice of nanodisk lasers emulating a lattice of FM coupled magnetic spins. (C), (D) Similar geometries for nanodisk cavities lasing in a TM21 mode, where an AF exchange interaction is expected to arise between nearby elements.
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