Nintendo Systems

Sega Systems

PlayStation Systems

Microsoft Systems

Microcomputers
System	Composite	S-Video	480i Component	480p Component
Xbox	Composite - Xbox	S-Video - Xbox	480i (SD) - Xbox	480p - Xbox

Miscellaneous Systems
System	Composite	S-Video	RGB	Component
3DO Interactive Multiplayer	Copmposite - 3DO	S-Video - 3DO	RGB Unsupported	Component Unsupported

Side-By-Sides
Saturn
Dreamcast
Genesis
Xbox
Nintendo 64

Advanced Features

1080p Output Modes

The RetroTINK-5X Pro offers four 1080p output modes in the Output menu: 1080p (Fill), 1080p (Over) and 1080p (Under). These modes interpret the input video signal in different ways, and understanding their function will help get the most out of the RetroTINK-5X Pro. Note that Scaling and Crop adjustments are still required in many cases to position the image and crop out unwanted video artifacts. The example Super Mario Bros. images were captured with stock generic settings with minor alignment and cropping adjustments.

1080p (Fill)
1080p (Fill) Example	In 1080p (Fill) output mode, the video source will be enlarged to fit the vertical boundaries of the 1080p screen. Pros: None of the video information is cropped, all of the vertical screen space is used. Cons: Somewhat softer image due to the non-integer scaling.
1080p (Over)
1080p (Over) Example	In 1080p (Over) mode, a 240p signal will be multiplied five times and 480i / 480p are multiplied 2.5 (2.5x) times. The output will slightly exceed the vertical edges of the 1080p frame and be cropped at the top and bottom. Many retro games accommodate this cropping, as they were intended to be played on CRTs that typically concealed the edges of the picture in the overscan \ bezel area. Some games, such as those on the SEGA Master System, do not render graphics at the system's full vertical height, and thus won't have any rendered graphics cropped in the 1080p (Over) mode. Pros: Larger playfield due to the 5x scale and sharp image thanks to integer scaling. Cons: Vertically cropped image.
1080p (Under)
1080p (Under) Example	Selects the 1080p (Under) output mode. In this mode, a 240p signal will be multiplied four times and 480i / 480p are multiplied twice. The video output will be centered on the screen with a black border. Pros: Sharp integer scaled output. Cons: Smaller image / unused 1080p screen space.

Video Modes

An important element to unlocking the advanced features of the RetroTINK-5X Pro is knowing the specific video mode your console is outputting. This isn't always easy - video modes can change depending on your cable type, game selection, console menu options or even settings within the game. In some cases, video modes will change in-game, often between in-game menus and gameplay (see Triple Buffer vs Frame Lock And Gen Lock for more information on the 'Chrono Cross' problem). Thankfully, the RetroTINK-5X Pro handles the hard work and adjusts seamlessly behind the scenes to process nearly anything your video game console can throw at it. However, understanding your console's video modes can open up advanced tuning options to dial in your console and video preferences.

A Video Mode, simplified, is the number of vertical picture lines a console is generating, followed by either a p or an i, or Progressive and Interlaced respectively - e.g., 480p. For this section, the differences between Interlaced and Progressive will be the focus. (For a complete list of compatible input video modes, see the Input Source section of the wiki.)

Interlaced Signals

Interlaced video is a video standard that dates back to the dawn of broadcast television, and was mainly a technology used on standard definition CRT displays. With interlaced video, the image is drawn on the screen from top to bottom in two consecutive passes. The first pass draws the image in the even spaces, and the second pass fills the image in the odd spaces. This process happens quickly to create a smooth persistence of motion. This "tik-tok" method of filling in the screen allowed early engineers to get more out of the limited bandwidth of TV broadcast signals.

While interlaced video is still used in certain situations, modern display technology doesn't process video in the same way, and interlaced video has to be converted into a progressive image before it can be drawn. The process of turning an interlaced video signal into a progressive one is known as deinterlacing. While Motion Adaptive Deinterlacing is the most sophisticated and is the default deinterlacer on the RetroTINK-5X Pro, there are situations where other deinterlacing methods can create desirable effects, such as Bob and the corresponding Bob Scanline Modes. More about the The RetroTINK-5X Pro's deinterlacing options and examples are outlined in the Interpolation/De-interlacing section of the wiki.

Progressive Signals

Unlike interlaced video, progressive video modes are drawn to the screen in one pass, and thus do not require deinterlacing to be drawn on modern displays. Common progressive modes found in retro consoles include 240p, 480p, and 720p. Because they do not require additional processing, they are typically seen as a higher quality signal (often described as sharper or cleaner) and in most cases are preferred over interlaced options. Progressive video modes can also be processed using the RetroTINK-5X Pro's Pre-Scaling functions for additional resolution-dividing and scanline effects.

NTSC and PAL

oof placeholder

Determining Video Modes

Below is a table of common consoles and their supported video modes. Note that some consoles can be modified or use software to support video modes beyond what is shown here. However, this should serve as a good "rule of thumb" for what video modes and cables are required to get a good experience using them with the RetroTINK-5X Pro. More information for specific consoles can be found in the Console Specific Configurations section.

Video Modes Table

Downscaling

Downscaling is a feature of the RetroTINK-5X Pro to output certain resolutions the same or lower than the source input. Specifically, 240p, 480i, 480p and 720p inputs can be output as 240p or 480i. Common use cases include converting modern resolution video games to be compatible with standard definition displays, and for non-deinterlaced 480i VHS capture. Typically, a second transcoder is used to take the HDMI output of the RetroTINK-5X Pro and convert it to an analog signal the SD-compatible display accepts.

All HDMI-capable consoles offer a 720p mode as of 2022, however you may need yet another transcoder to convert the signal to Component, since the 5X does not have an HDMI input. Certain "HD" consoles do allow for Component output, including the PlayStation 3 and most Xbox 360 models.

Enabling the "Ds Pass-Thru" setting will configure the RetroTINK-5X Pro to automatically change the output to follow the source input. For example, if a 480i input was detected, the output would be 480i. If The "Ds Pass-Thru" toggle was set to "off" (default), the 480i input would be processed and output at whatever resolution was set in the "Output Resolution" menu.

• The video above is My Life in Gaming's video covering 240p downscaling using the GBS 8200 with the GBS-Control custom firmware. The knowledge and experiences learned there will generally apply to the 5X as well, including trying to fit a 16:9 image into a 4:3 window, and how high-resolution games and pixelart games may not scale down pleasantly to 240p.

Triple Buffer vs Frame Lock And Gen Lock

Older video game consoles didn't always have perfect video timings. CRTs typically had no problems working with these variances, but these "imprecise" consoles can sometimes have trouble working with modern TVs and capture devices that conform to a more rigid standard. Some games, such as Silent Hill or Chrono Cross on the PlayStation 1, will alternate between 240p or 480i video modes if you are in-game or in the items/pause menu, respectively. On many displays, upscalers and capture devices, this will create a long delay and a "no input detected" screen for several seconds while the device reorients to the new video mode. The issue of a device taking a gameplay-harming amount of time to change between video modes has been colloquially called the "Chrono Cross" problem.

• These modes can be accessed in the "HDMI" menu, then adjusting the "V-Sync" option.
• For PAL users, it's worth noting that the Lock to 60hz feature may also be required to remove the "Chrono Cross" problem.
• Lock to 60hz also allows capture cards to not lose picture when nothing is output at all, such as before and after the console startup.
• The TINK-5X is not able to automatically switch its H. Sampling Preset when the resolution changes. If you are using one of the non-Generic presets, we recommend using the one that matches the gameplay.

Triple Buffer
The RetroTINK-5X Pro uses "Triple Buffer" mode to effectively eliminate the "Chrono Cross" problem and create very high compatibility with displays and capture devices even for consoles with "imprecise" video. However, Triple Buffer mode comes at the expense of increased lag and occasional and minor judder. The lag varies between approximately 0.25 to 1.25 frames in this mode.

Frame Lock
For those looking for the lowest possible lag, the RetroTINK-5X Pro offers a "Frame Lock" mode. With Frame Lock enabled, the RetroTINK-5X Pro uses the console's video input as its base clock and offers a fixed lag of approx. 0.25 frames. The lowered lag comes at the cost of possibly lower compatibility with some TVs and capture cards, and not protecting devices from the "Chrono Cross" problem.

The RetroTINK-5X Pro defaults to Triple Buffer mode to ensure the highest compatibility for users. To toggle between Triple Buffer and Frame Lock, navigate to the HDMI settings and toggle the V. Sync (Vertical Sync) option.

Gen Lock
The 'Gen Lock' feature is only available with Firmware 2.73 or higher, and only on units sold after July 2021. This variance is due to a part that was substituted on account of supply shortages. Firmwares 2.73 and above will still work with older models (including newer features such as HDR), but won't display the Gen Lock feature.

Similar but unique to Frame Lock Mode, Gen Lock allows the RetroTINK-5X Pro to match the input frame rate with a regenerated clock, resulting in a signal which is more stable than Frame Lock Mode. Mainly useful for 1440p+ resolutions with SDP sources (Composite/S-Video) that previously could not sync in Frame Lock. Other benefits include removing judder and composite artifacts that show up in triple buffering, as well as dejittering the SNES for displays that may otherwise not work in Frame Lock Mode.

Variable Refresh Rate (VRR)

Certain displays support Variable Refresh Rate, allowing them to achieve a wider range of frame rates. The RetroTINK-5X can flag its output as VRR, which improves input lag for the Frame Lock and Gen Lock V-Sync modes. For certain displays this will also enable a special low latency mode, reducing the display's input lag. Input lag can be further reduced by setting the 5X to "1080p (Min-Lag)" in the output menu.

• To enable VRR, go to the "HDMI" Menu and set VRR to "FreeSync".

Horizontal Sampling Modes

The TINK-5X uses a combination of its flexible video ADC plus polyphase scaler to produce various horizontal sampling options. The Generic 4:3 and 16:9 modes interpolate the horizontal directions to produce the correct aspect ratio at the select output resolution.

The optimal modes, listed for the various consoles, sample the horizontal direction at the same rate as the original console, allowing for an even sharper picture. Here are the currently included "Optimal Timing" presets:

Post Processing Filters

The RetroTINK-5X Pro features customizable post processing filters designed to simulate the look of certain CRT and LCD displays. Below is a list of the current featured presets, as well as examples captured from the same video source for comparison and reference. To view the post-processing effects example images with the best clarity, click once to view the images enlarged, and click the enlarged image again to view them in your browser without scaling.

Preset	Off	Slot Mask	A. Grille -1	BVM
Description	Off (No Filter)	Slot Mask Preset	A. Grille-1 Preset	BVM Preset
Preset	PVM-600	FV310	Consumer-1	Consumer-2
Description	PVM-600 Preset	FV-310 Preset	Consumer-1 Preset	Consumer-2 Preset
Preset	LCD (Optimal Horizontal Sampling)	LCD (Generic Horizontal Sampling)
Description	LCD Preset - The LCD filter while using an optimal Horizontal Sampling preset. Creates a black border around individual pixels to simulate the look of a retro LCD screen, reminiscent of a Game Boy or Game Gear display.	LCD Preset using a generic Horizontal Sampling preset. Creates ultra-thin horizontal scanlines.

HDR

"Inject HDR" can be used with compatible displays to treat the RetroTINK-5X Pro's HDMI output as "HDR enabled-content." This allows extended range of the +Gamma Boost value in the Post Processing menu to compensate for the loss of image brightness when using Scanline and/or CRT Mask filters, as well as the display's Black Frame Insertion feature. Without "Inject HDR" enabled, +Gamma Boost operates at a range of -10 to +10. With "Inject HDR" enabled, the range is increased to -10 to +20.

• To enable HDR, navigate to the [HDMI] selection from the RetroTINK-5X Pro GUI and set "Inject HDR:" to either "HLG" or "HDR10".
• HDR is intended to be used with the 5X's scanline presets found in the "Post Proc." menu.
• Note that HLG will look very de-saturated at first; you must go to the [Post Proc.] menu and adjust "Color Boost" to 0.

HLG and HDR10 are different formats of HDR, and from the RetroTINK-5X will appear different from each other. HDR10 is more luminous, and with scanlines can help mimic the brightness of a real CRT, but can appear garish without scanlines. HLG isn't as luminous, but is more pleasing without scanlines. The CRT look can be mimicked even further if your display is capable of Black Frame Insertion (BFI).

Note that HDR isn't well represented in screenshots, and that the effect is more pronounced when viewed in person on an HDR display.

In the table below, all photos have had their exposure set for HDR10 with PVM-600 scanlines, to demonstrate the brightness differences between the various examples. Since they're photos of a screen, the contrast is not representative of looking at them with the human eye. The TV used was an LG CX 55".

HDR Comparisons - Off-Screen Photos
	HDR10	HLG	SDR
PVM-600 Scanlines	Gamma Boost: +10, Color Boost: +0 (Default)	Gamma Boost: +7, Color Boost: +4 (non-default)	Gamma Boost: +0, Color Boost: +2 (Default)
No Scanlines	Gamma Boost: +10, Color Boost: -5 (non-default)	Gamma Boost: +5, Color Boost: -2 (non-default)	Gamma Boost: +0, Color Boost: +0 (Default)

This second table shows what the HDR modes look like via direct capture.

HDR Comparison Examples - Direct Captures
CRT mask/scanlines and HDR disabled	BVM Scanlines (HDR disabled)	BVM Scanlines (HDR enabled)

Pre-Scaling and Bob Scanline Modes

Pre-Scaling

The RetroTINK-5X Pro includes the ability to "Pre-Scale" progressive video content, or discard scanline intervals, at one-half or one-third increments of the source input. This discards vertical lines resulting in a loss of resolution and visual information, and isn't always a desirable effect. However, this loss in resolution is useful in some circumstances, such as more accurate scanline rendering for 240p visual content output from consoles that run at higher resolutions (such as the Dreamcast or Wii). The following example is from Street Fighter 3: Third Strike for the Dreamcast. The Dreamcast is outputting 480p, but the assets of the game are 240p graphics being doubled in software. The RetroTINK-5X Pro can throw away half the redundant visual data before applying post-processing effects, resulting in a more "arcade CRT authentic" scanline size and effect.

More information can be found at the Post-Processing Filters, Post-Processing, and Interpolation/Deinterlacing sections.

No Scanline Effects	Scanline Post-Processing with No Pre-Scale	Scanline Post-Processing with 1/2 Pre-Scale
This example was achieved by setting the Scanline to Gaussian and Scanline Str. to 50 in the Post-Processing section, and setting Prescale to 1/2 in the Interpolation/Deinterlacing section.

Bob Scanline Modes

Much like pre-scaling for progressive content, Bob Scanline Modes gives you additional control for how scanlines are applied with 480i interlaced content. To use the various Bob Scanline options, the Deinterlacer must be set to "Bob" in the Interpolation / Deinterlacing menu, and scanlines should be enabled in the Post-Processing menu (any preferred combination of "+Scanline Beam" and "+Scanline Str." settings).

The "Post-Deint." or Post Deinterlace option applies scanlines after the 480i source has been deinterlaced to 480p. This gives the appearance of thinner scanlines.

"Pre-Deint. or "Pre-Deinterlace" treats the 480i source as 240p, so the applied scanlines are thicker. This is especially appropriate for situations where a 240p graphical asset game is being displayed in a 480i video mode.

The "CRT Simulate" setting functions similarly to Pre-Deinterlace, but shifts the odd and even scanlines every frame to reproduce how a CRT display would draw the image.

For more information on deinterlacing methods, please see the Interpolation/De-interlacing.

Below are some examples from Mega Man Anniversary Collection on the PlayStation 2. It is an example of a game that renders 240p assets through 480i video output. This is not typically a desirable combination for the best video quality, but using Bob Scanline modes and scanline Post Processing filters can help improve the visual experience of the game.

Saving and Loading Profiles

The RetroTINK-5X Pro includes 10 slots to save your custom settings. To save your settings, navigate to the [Save Profile] section from the Main Menu. Selecting one of the Save Profile slots (1-10) will save any current changes made to the RetroTINK-5X Pro system into the chosen slot.

As of firmware 2.98, selecting a slot to save a profile will bring up a secondary window allowing you to name your profile with an on-screen keyboard. The saved values can then be loaded from the Load Profile menu, or a slot be set to load on boot from the On-Screen Display/Startup Profile selection.

The Load Profile menu also allows you to go to the Default Profile; this isn't visible in the Save Profile menu to prevent the user from accidentally overwriting it. You can also load the Default Profile by quickly pressing the Back button on the remote six times.

Console Specific Configurations

This section goes over the specific settings and configurations you may want to consider for specific platforms, including their quirks such as the Nintendo 64's additional blur filters, or counteracting the 3DO's 480i output. Please keep in mind that the RetroTINK-5X Pro still provides a great experience without diving into any of this so that you can Just Play The Damn Game^TM.

This section in particular delves into what is known as "Optimized Sampling". This process further refines the picture to gain the sharpest pixels possible by dialing in to the specific resolution the game is currently outputting. This comes at the expense of freely resizing the picture like in the Generic 4:3 and Generic 16:9 modes: doing this with Optimized Sampling will result in undesired results. This, combined with the pixel aspect ratios many retro games expected to be viewed on, means that Optimized Sampling is frequently at the mercy of integer-based scales. If that all sounds complicated, stick to the Generic 4:3 / 16:9 modes so you can resize to your heart's content.

The Optimized Sampling Settings in this section are transcribed from Wobbling Pixels' YouTube channel, where he creates excellent video guides to dial in optimal settings for various retro gaming consoles and configurations.

SNES / Super Famicom

The SNES' optimal sampling settings are simple, since it has a specific preset you can use for the vast majority of its games. Go to "H. Sampling", set the Preset to "SNES/PCE 256", then reposition the image to the center of the screen in the "Scaling/Crop" menu.

1CHIP Vs 3CHIP Video Output

A quirk of earlier SNES models is a rightwards horizontal streaking of the image, resulting in a "murkier" picture. This effect is found to various degrees in all "3CHIP" SNES consoles, named after the numerical count of processors and video processing chips used on the console's main board. Later model SNES consoles have a revised design, and notably consolidated the CPU and video processors in a single package. These versions of the SNES are colloquially referred to as "1CHIP" consoles (this includes the slimmer SNES "Jr.", however the SNES Jr does not support RGB output without modding).

The "1CHIP" SNES design eliminated the horizontal streaking artifact, while increasing the overall brightness of the video output. The brightness boost is noticeably more vibrant, but without correction can "clip the whites" and cause some brighter details to be lost (the HD Retrovision SNES Cable has a selectable mode specifically for this issue). Despite the downsides, the "1CHIP" is still typically favored over "3-CHIP" models.

While The TINK-5X cannot completely remove the streaking found with "3CHIP" video output, it can help mitigate the effect. Try using a scanline preset in the 5X's "Post Proc." menu and setting the Pre-emph to a negative value. The CRT filter should help to obfuscate the horizontal blur and the negative pre-emph will apply a sharpening effect.

3CHIP and 1CHIP video solutions
Non-1CHIP SNES.	Non-1CHIP SNES w. Aperture Grille.	1CHIP SNES.	1CHIP SNES w. HD Retrovision brightness adjustment.

Super Game Boy 8:7 Settings

If you're using the Super Game Boy, you'll want to use its own optimized sampling numbers when using it. This is because Game Boy games were expected to be displayed on the square pixels of a Game Boy screen, unlike the rectangular CRT pixels that the SNES expects. While not perfect squares, the 8:7 aspect ratio of the numbers provided above will give proportions that are much closer to an actual Game Boy, and so is a more accurate look. The Super Game Boy's borders however were intended to be shown on a CRT, and thus will look more accurate with the SNES optimized sampling numbers.

In the Pokémon Yellow examples below, note how the Pokéball in the game window is a perfect circle with the Super Game Boy's sampling but is squashed with the SNES' sampling. Meanwhile, the Pokéballs in the border are correct with the SNES' sampling.

8:7 Aspect Ratio Examples
Pokémon Yellow - SNES optimal sampling	Pokémon Yellow - Super Game Boy optimal sampling	240p Test Suite Monoscope	Super Mario Land - Correct aspect ratio

Nintendo 64

Similarly to the SNES, optimal sampling for the Nintendo 64 is simple thanks to a preset just for it that works for many games in its library. Simply go to "H. Sampling", set the Preset to "N64 320", then go to the "Scaling/Crop" menu to center the image.

Counteracting N64 Anti-Aliasing

The Nintendo 64 uses an anti-aliasing (AA) effect to smooth the picture and reduce the appearance of hard pixel edges and dithering. Users that prefer a sharper look have the option to disable the N64's AA with GameShark codes, or by patching the game ROM. More information regarding methods to disable AA can be found here.

The RetroTINK-5X Pro's optimal Nintendo 64 sampling can also greatly increase the sharpness of the image, and can be used in conjunction with the disable-AA methods for the sharpest possible picture. For many, optimal sampling alone may provide results equivalent to an Anti-Aliasing patch.

The following examples are from Mario Kart 64, using S-Video cables in the Peach example and RGB cables in the Track example. The images show the RetroTINK-5X Pro's generic and N64 optimal sampling modes, as well as with and without disable-AA patches applied.

Nintendo 64 Anti-Aliasing Comparisons
Generic Sampling	Optimal Sampling		Generic Sampling	Optimal Sampling
Generic Sampling with Disable-AA Patch	Optimal Sampling with Disable-AA Patch		Generic Sampling with Disable-AA Patch	Optimal Sampling with Disable-AA Patch

GameCube

GBA Player

The GameCube supports a peripheral called the GBA Player, which allows Game Boy Advance games to be played via a GameCube, similar to the Super Game Boy on a SNES. However, the GBA Player used software with a blurry and otherwise undesirable video output. To get around this, many players use an SD card and SWISS to load a replacement program known as the Game Boy Interface, which has a much improved video output. The Wobbling Pixels video above shows how to get this working on your GBA Player.

When the RetroTINK-5X detects the 360p output of the Game Boy Interface, a special "GBI Optimal" Preset can be found and selected in the "H. Sampling" menu. This automatically enables optimized sampling just for the Game Boy Interface.

For a more authentic look, you may want to consider enabling the LCD Scanlines preset in the "Post Proc." menu, which overlays a thin pixel grid that looks a lot like a Game Boy Advance screen. Keep in mind however that due to their thin width, LCD Scanlines only display correctly for GBI when using the 1080p (Fill), 1200p and 1440p Output Resolutions.

Dreamcast

If you're using the Dreamcast's VGA output, optimal sampling is made easy since there are easy presets just for it in the "H. Sampling" menu, which will work for most of its games library. Which one you pick depends on the output set in the 5X's "HDMI" menu.

• If your output is 1080p (Under), choose the "DTV 858-A" Preset.
• If your output is 1200p, choose the "Generic 3:2" Preset. You should also go to the "Post Proc." menu and set the Pre-emph to +1, which sharpens the image a bit.

Dreamcast VGA on the 5X

The highest quality video output of the Sega Dreamcast without modding is VGA (31Khz RGBHV). Most games on the Dreamcast support VGA output, and workarounds exist to extend the feature to even more titles (such as patches and the "force VGA" functions of the optical drive emulators GDEMU and MODE). A chart showing Dreamcast VGA compatibility can be found here. Old Kid's Note: We should convert that guide to the wiki!

Currently two kinds of options exist to bring VGA signals into the RetroTINK-5X Pro, 'Sync Combiner Boxes' and a 'Sync Combiner "All-in-One" Cable':

Sync Combiner Boxes
The RetroTINK-5X Pro requires that the Dreamcast's VGA signal be converted (RGBHV sync-combined to RGBs) to work with the 5X's RGB-SCART input. Thankfully, devices such as the HD15-2-SCART, VGA2SCART can make that conversion.

Note that both the HD15-2-SCART and VGA2SCART will require existing VGA and audio cables from the Dreamcast's output. The Retro-Bit Dreamcast VGA Cable is an inexpensive, respectable quality option to get VGA and stereo sound from the Dreamcast, but generic "Dreamcast VGA Cables" and dedicated "VGA Boxes" can work similarly.

Once the Dreamcast is connected to either sync combiner box, The HD15-2-SCART plugs directly into the SCART input on the RetroTINK-5X Pro, while the VGA2SCART will require a male-to-male SCART adapter (such as the one linked here) or a "male-end to male-end SCART cable" to make the connection.

The HD15-2-SCART provides a switch to enable/disable the sync combining feature (which possibly could be a benefit when using with other devices that support RGBHV over SCART) while the VGA2SCART's sync combiner feature is 'always on'.

A note concerning audio - Both HD15-2-SCART and VGA2SCART receive audio over a stereo 1/8" TRS jack, so "Retro-Bit Style" VGA cables will require a Stereo RCA to 1/8" TRS adapter for audio to be routed into the boxes.

The benefit of using the "Sync Combiner Box" solution is flexibility. While the RetroTINK-5X Pro isn't specifically designed to process other VGA inputs and compatibility isn't guaranteed, using a "Sync Combiner Box" can give you the option to plug in other VGA sources, or to use the Box with other devices or video processors.

Sync Combiner "All-in-One" Cable
The Retro Access 15Khz/31Khz Dreamcast Cable and Sega Dreamcast PACKAPUNCH RGB 480p SCART cable are all-in-one "VGA to SCART" cables for the Dreamcast that do not require any additional hardware. The sync combiner circuit is built into the cable and unlike the "Sync Combiner Boxes", they won't work with any other device than the Dreamcast. Both cables feature the function to switch between 15Khz and 31Khz RGBs signal output, providing the option of outputting 480p or 480i video modes. While 480p is typically preferred as the higher quality video mode, the RetroTINK-5X Pro can accept and process both outputs.

Dreamcast "VGA" Examples
Dreamcast 31Khz VGA Output (Retro-Bit VGA Cable + VGA2SCART)	Dreamcast 31Khz VGA Output (Retro Access 5khz/31khz 480i/480p SCART Cable)	Dreamcast 15Khz VGA Output (Retro Access 5khz/31khz 480i/480p SCART Cable)

PlayStation 1

Optimal sampling on the PlayStation 1 is a very complicated affair, because it has a large number of possible output resolutions, meaning you can't just "set it and forget it". Instead, you'll almost certainly need to set up and use multiple Profiles that accommodate for the various output resolutions the games in your library may have. We highly recommend checking the output resolution of each of your PlayStation 1 games so that you only have the Profiles you actually need. You should also commit to which output resolutions you want to use: trying to accommodate for all of them would require 30 or more Profiles!

Further, pixel aspect ratio will be incorrect for many combinations of the game region, H.Sampling preset and the 5X output. If you want to use optimal sampling, read over the table above carefully to make sure you're picking the right preset, and using the right "H (Interp) Size" numbers and "V Size" numbers. For V-Size, look for the number in the white box in the bottom-right corner of the Scaling/Crop window: when this reads "1.00", you've matched the intended pixel aspect ratio!

Resolution Switching

The PlayStation 1 library occasionally uses more than one output resolution within the same game. One of the most famous examples is Chrono Cross, where gameplay is in 240p while the pause menus are in 480i (hence the common name, "The Chrono Cross Problem"). While resolution switching worked fine on the CRTs that the PS1 expected to output to, almost all modern flat-panel displays, as well as many capture cards, take some time to switch, resulting in several seconds of no display at all. This pause can not only be frustrating, but risky when returning to gameplay, where you'll be blind to all threats until the image returns.

The RetroTINK-5X has two methods to get around this, both located in the HDMI menu:

• Setting the V-Sync to either Triple Buffer or Gen Lock is usually enough to alleviate the issue, at the cost of a hair of input lag.
• If you're still encountering this issue (particularly in PAL games), also setting "Lock to 60 hz" to On will often solve the issue entirely.

It's worth noting that the TINK-5X is not able to automatically switch its H. Sampling Preset when the resolution changes. Thus, we recommend using the Preset that matches the gameplay resolution and sticking with that. Using Generic 4:3 is also an option, although the image will of course not be quite as sharp as optimal sampling.

PlayStation 2

Since the PlayStation 2 is compatible with PlayStation 1 games in addition to its two "480" resolutions, it has one of the highest number of possible output resolutions of any games console, and so is just as complicated. We strongly recommend researching what resolutions your PS1 and PS2 games output so that you aren't using any unneeded Profile slots.

All advice outlined in the PS1 section above applies here. Even if you're just playing PS2 games on a PS2, there are two possible resolutions that can be output, so if you want to use optimal sampling, you'll need to check the resolutions of the games in your library, then save the optimal sampling settings to two Profile slots. This is simpler than it sounds: since there's only two possible resolutions for a PS2 game, you only have to flick between the two Profiles and choose the one that looks correct.

It's also worth noting that the PlayStation 2's "240p" resolutions require different numbers than the PlayStation 1. We advise users with both a PlayStation 1 and 2 to play PS1 games on a PS1, to keep the needed Profiles to a minimum.

Finally, it's important to stress that the vast majority of PlayStation 2 games can only output interlaced video: 480i. Some games allow you to use a button combination when the game boots to enter a progressive output mode, or in the options menu, but few games allow for this, and the button combo trick doesn't exist in PAL games. Motion Adaptive de-interlacing can help and is typically more appealing than Weave, Blend or Bob, but does have its own weave-like artifacts that are most prominent in 3D action games and other titles with fast movement. No solution to interlaced content will be perfect, and the only remedy is if the game will output true progressive video.

If you're using optimized sampling, it's important to enable the "Allow Interlace" option in the H. Sampling menu, otherwise your adjustments will not appear correctly on interlaced resolutions!

PlayStation Portable (PSP)

In the Optimal Settings above, "No Scanlines" will stretch the image to fill your display while maintaining the PSP's 30:17 aspect ratio. The "Scanlines" setting meanwhile adjusts the picture slightly so that scanlines are drawn correctly (such as LCD scanlines), but the aspect ratio will be slightly incorrect. In either case, sometimes the H Position and V Position values won't line up correctly, so we recommend manually adjusting these yourself so that the picture is centered on your display.

The specific model of PSP you're using will determine whether it's capable of Video Out, and to what extent:

• The original PSP model (PSP-1000) and the PSP Street (PSP-E1000) do not support Video Out.
• The PSP-2000 is capable of Video Out, but only using Component cables. PSone Classics can also not be played using Video Out on this model.
• The PSP-3000 can do Video Out using Composite, S-Video and Component cables, including with PSone Classics.
• The PSP Go is also capable of Video Out for all content, but only when using an official dock. Because of this, it requires a different cable.

We highly recommend you use Component Cables when using a PSP-3000 / Go with the RT5X. While the 5X works with PSP Composite and S-Video signals just fine, because the video output is so small within the 480p frame, it's not possible for the 5X to fill the entire screen with PSP output on anything except Component.

PSone Classics

It's possible for PSone Classics running on a PSP to output at their native 240p resolution. To enable this, on your PSP navigate to Settings > Connected Display Settings, then set the "Component / D-Terminal Output" setting to Interlaced. This will result in a sharper picture through the TINK-5X than the Progressive option.

However, you cannot use either the PS1 or PS2 Optimal Sampling numbers from earlier on this page, as they work incorrectly with the PSP's 240p output. For now, we suggest using the "Generic 4:3" H. Sampling preset with the "1080p (Fill)" Output, or using real PS1/PS2 hardware.

PlayStation TV + Sharpscale Hack

The PlayStation TV (known as the Vita TV in Japan) is a popular way to play digital PSP, Vita and PSone Classic games on a TV, thanks to its compact size and compatibility with DualShock 3 and 4 controllers. However, it does not correctly display or upscale its picture, and adds a bilinear filter to all video output by default. You can however use a popular homebrew plugin called the Sharpscale Hack by Cuevavirus to open up new options, and combine it with the 5X to get a pixel perfect upscale of PSP, Vita and PSone Classics games. First though, two notes:

• The Sharpscale Hack is a plugin for a homebrew firmware called h-encore², which you'll need to have installed in order for this to work. Without it, there's no benefit routing the signal through the 5X.
• Since the PSTV can only output via HDMI (which the 5X cannot accept), you'll need to convert the HDMI signal to component, as detailed in the "HDMI consoles" section further below. Make sure to read this section carefully, as high-definition signals are not the initial intended use case for the 5X.

PSVita and PSP Games

Here's how to set up the Sharpscale Hack and the RetroTINK-5X when playing PSP and Vita games on PSTV (PSone Classics have their own section below):

1. First, in the Sharpscale Configuration Menu app, set Scaling to "integer" and Filter to "point".
2. Set the PSTV's output resolution to 1080i. With the above Sharpscale settings, this will fill the screen for Vita and PSP games, at the cost of cropping out 4 pixel rows each on the top and bottom of the screen.
3. On the RetroTINK-5X, apply the optimal sampling settings in the table above.

PSTV Vita / PSP Sharpscale Comparison
Direct HDMI capture, Sharpscale disabled.	Component via RT5X, Sharpscale enabled.	Direct HDMI capture, Sharpscale disabled.	Component via RT5X, Sharpscale enabled.

PSone Classics

Because of the unique resolutions of PSone Classics and the limitations of the PSTV, these titles have to be handled differently compared to PSP and Vita games. There are many different combinations you can try for the PSTV and RT5X's resolutions; here are our two recommendations:

• The PSTV can output 480p, which is a natural fit for the 5X:
  • Set the PSTV to output 480p (2x the resolution of PSone Classics)
  • In the 5X, go to the "Interp./Deinterp" menu and set the Pre-scaler to 1/2 (half).
  • Apply the Optimal Settings listed in the table above.
• Alternatively, the PSTV's 720p output allows for clean scaling to 1440p:
  • Set the PSTV to output 720p (3x the resolution of PSone Classics)
  • Go to the 5X's "Interp./Deinterp" menu and set the Pre-scaler to 1/3 (a third).
  • In the 5X's OSD menu, make sure "Advanced Res." is set to "Yes".
  • In the 5X's Output Res. menu, select "2560x1440".
• In all cases, in the Sharpscale Configuration Menu app, set the PS1 Aspect Ratio to "4:3". This will ensure the correct aspect ratio at all times, but at the cost of uneven pixel scaling that is only apparent in 2D games.
• PSone games cannot be played in 1080i: if you attempt this, the PSTV will switch to 720p until the game is close. As a result, you may need to swap between two different PSTV output resolutions and 5X Profiles.

PSTV PSone Classic Sharpscale Comparison
Direct HDMI capture, Sharpscale disabled.	Component via RT5X, Sharpscale enabled.

3DO

Optimal Settings

3DO 240p Video Output Methods

The 3DO renders video to a native 240p frame buffer, then puts it through a proprietary "corner weight color averaging interpolation" algorithm that up-converts the video to 480i. The algorithm can be set between the "corner weight color averaging" or a simple "nearest neighbor" upscale depending on the 3DO software. While the "corner weight color averaging" algorithm used in many games gives increased color depth and smoothing to the image, some may prefer the less flickery and sharper native 240p output.

Some "FZ-1" 3DOs from Japan have a special Mode Select switch on the back in place of the RF output, which allows switching between Mode A, standard 480i output, and Mode B, native 240p video output. Mode B can also slightly improve the performance of some games, while other titles may run incorrectly in this mode, such as Out of This World, which runs too fast. The Juxtaposition Image below demonstrates the visual difference between 480i and 240p from a 3DO featuring the "Mode Select" switch.

"Pseudo-240p" With The RetroTINK-5X Pro

If you don't have a 3DO with a Mode Select switch, or don't want the possible side-effects of setting one to Mode B, the RetroTINK-5X Pro offers a deinterlacing method that can simulate a 240p look with a 3DO with no Mode Select at all: "Pre-Deinterlacing" Bob Scanlines.

• To accomplish this Pseudo-240p method, go to the TINK-5X's "Interp./Deint." menu and adjust the following settings:
  • Deinterlace Method: Bob
  • Bob Scanline: Pre-Deint.

This will effectively ignore half of the 480i video lines and scale the image as a "pseudo-240p" source.

It's worth noting that not all games will see a visible improvement with this method. Titles that do not use the "corner weight color averaging interpolation" feature will look almost identical between "240p" and "Motion Adaptive" modes, whereas games that do use the color interpolation effect may have a beneficial sharpened look in "240p" processing mode. See the table below for examples. More info concerning the "corner weight color averaging interpolation" algorithm can be found at 3dodev.com

3DO Special Processing Examples
Out of This World with Motion Adaptive Deinterlacing, matching the FZ-1.	Out of This World with the FZ-1's "Pseudo-240p" Pre-Deinterlace Mode	Road Rash with the 5X's Motion Adaptive Deinterlacing. Here, there is no visible gain.	Road Rash with the FZ-1's "240p" Pre-Deinterlace Mode

Below are some comparisons between the RetroTINK-5X Pro's Bob Scanline Pre-Deint mode and a special model 3DO that has a 240p / 480i switch built in:

3DO "Real 240p" Vs. "Pseudo-240p"
3DO - Super Street Fighter 2 Turbo - 480i	3DO - Super Street Fighter 2 Turbo - "Real 240p"	3DO - Super Street Fighter 2 Turbo - "Pseudo-240p"

RF Consoles

Before Composite and later video signal formats, many video game systems used radio frequency (RF) signals to output video and audio to televisions, including the Super Famicom and systems released before it. The RetroTINK-5X Pro does not accept RF signals directly, however it is possible to use an RF demodulator to pass composite video and RCA audio to the RetroTINK-5x's inputs.

While other methods exist, the most common and cheapest RF Demodulator is a standard consumer VCR.

Standard Consumer VCR

As of writing, VCR’s can still commonly be found in second-hand stores. Make sure the model you intend to use has both RF Inputs (typically labeled as Antenna In) and Composite Outputs (the Yellow, Red and White output jacks for the video and audio), indicating that the VCR supports RF Demodulation. Note that it is not typically required for the VHS tape playback hardware be functional to use the demodulator features, but a fully working VCR allows you to use the RetroTINK-5x as a VHS upscaler.

Two common types of cables to connect the console to the VCR are RF Switch Boxes and RCA to F-Type "RF Direct" Connectors:

Cables to Connect Console To VCR
NES / SNES RF Switch Box	RCA Plug to F-Type Screw Connector Adapter

Your console might have one or the other, and either connection method is an acceptable way to interconnect the console and VCR. Note that some console has an RCA end but does not have an F-Connector adapter to plug into the VCR, and will need an inexpensive "RCA Female to F-Type Male" adapter to plug in. Here is a link to an Amazon search that should point you in the right direction.

RF switch boxes often came standard with consoles because they allow daisy chaining of RF inputs into one TV coax jack, and switch allow cable TV or antennas connected in tandem with the console to prevent frequent cable-swapping to change the TV's function.

Note that video game systems most often broadcast their signal over channels 3 or 4, and many times contain a switch to select between the two channels. There’s no reason to choose one over the other, but take note of the channel your console is set to, as the VCR will need to be set to that channel to receive the console's signal.

Connecting an RF Only Console to the RetroTINK-5X

In this example I am using an NES (which notably is not an "RF Only" console), but the steps are nearly identical to most consoles outputting RF signal: Make sure your VCR, video game console and RetroTINK-5x Pro are plugged in, turned on and functioning. Then:

RF Vs. Composite Comparison
RF - NES - Super Mario Bros 3	Composite - NES - Super Mario Bros 3

HDMI Consoles

On the opposite end of the spectrum, you may want to run an HDMI console such as the PlayStation 4, Xbox One, or one of the "Classic Mini" systems through the Retro-TINK 5X Pro. The 5X doesn't have an HDMI input, so many users will make this work by converting the HDMI signal to Component, which the 5X does accept.

It is worth mentioning that the 5X is primarily intended for use with consoles that output 240p, 480i and/or 480p resolutions. HD resolutions are technically supported, but they are not the intended use-case for the device. That said, here's how to make it work:

• Component signals will always look softer compared to HDMI, even at the same resolutions.
• We recommend using an HDMI-to-Component converter box with female Component ports, plus separate male-to-male Component cables.
• Make sure you don't accidentally buy a Component-to-HDMI converter, which is a more common product and easy to get confused with an HDMI-to-Component converter.
• The specific parts used in these converters can change based on parts availability, even for the same exact product. This can mean that a specific box can suddenly become incompatible with the 5X (or vice versa). To avoid this, make sure to check sites like RetroRGB for what the currently recommended converter is.

Here's what you need to consider for the consoles themselves:

• The RetroTINK-5X only supports two HD resolution inputs: 720p and 1080i. Make sure your console is outputting one of these two resolutions first.
  • 1080p input is not supported by the 5X.
  • If your intent is to downscale an "HD" system to 240p or 480i/p, 720p output is your only option, as 720p is the highest resolution the 5X can downscale.
• Certain consoles do not output 1080i, including the Nintendo Switch, Xbox One and Xbox Series X|S. You'll have to set these consoles to 720p instead for them to work with the 5X.
• Conversely, several systems support 480p output, including the Xbox 360, PlayStation 3, base PlayStation 4, and Nintendo Switch. 480p may be worth considering if your intent is to use the 5X to downscale to 240p.
• Many PlayStation 3, Xbox 360 and Xbox One games only supported 720p as opposed to 1080, so you may want to use 720p anyway for these systems.
• Certain HDMI consoles also support Component output natively, and thus do not need a converter at all to work with the 5X:
  • First, we again must note that Component video will always look blurrier than HDMI. While the 5X could be used as an effective "Component to HDMI" converter, this is NOT the intended use-case.
  • All Xbox 360s support component cables, with the exception of the Xbox 360 E revision which dropped the Xbox AV port that 360 component cables use.
  • The PlayStation 3 also supports component cables, including those intended for the PlayStation 2. If you're using the 5X purely to bypass the PS3's HDCP content protection (which is always present in its HDMI output but not its Component output), we suggest you instead look for a device that strips HDCP while keeping the signal HDMI, so that the picture looks its sharpest.
  • While the Wii U supports component cables (including those intended for the original Wii), its actual output of Component signals is rather poor. Further, its HDMI output is only in Limited Range, and cannot be set to Full Range. Thus, both Component and HDMI outputs have their own caveats with this system.

Mono Audio Consoles

Some consoles, such as the NES and Sega Master System, only provided a single mono audio output from their A/V hookups. Using a mono-only console will result in the RetroTINK-5X Pro sending sound through one speaker. Fortunately, using an RCA Y-Splitter with audio is a safe and inexpensive solution to this problem.

A Standard 1-Male to 2-Female RCA Y-Splitter

SAFETY WARNING: Using Y-Splitters correctly is safe for audio signals, but using them with video signals may cause damage to your video game console.

Mono-Only Console Audio Example
To hear a mono-only console output in both left and right sound channels on the RetroTINK-5X Pro, simply use a Y-Splitter to split the single RCA audio plug across two plugs to insert into the RetroTINK-5X Pro's stereo audio inputs. In the above example, a stereo red/white RCA pair is used and the signal is being split at the console using a 1-Male to 2-Female RCA Y-Splitter.

Dithering

Dithering is a technique of using pixel patterns to simulate an effect of additional color or transparency. Many retro video game consoles utilized dithering, though some games and systems relied on it more heavily than others. Traditionally, CRT displays could somewhat mask and blend dithering with their glowing phosphor and typically less precise handling of visual information, and it's arguable that this is the "intended look" the video game creators were expecting gamers to experience.

Modern displays using upscalers like the RetroTINK-5X Pro can emphasize dithering in a way that some users find undesirable, and for some games, users may want to configure a different approach than "sharp optimal settings".

Note that this is entirely subjective and up to the user's taste, and the RetroTINK-5X Pro can be configured in a variety of configurations based on the user's image preferences.

In the following image examples, the game Silent Hill for PlayStation 1 is used.

The first example shot emphasizes the game's dithering by using RGB cables and optimal sampling for the sharpest pixel appearance.

In the second example, the RetroTINK-5X Pro is using PlayStation composite cables with optimal PS1 horizontal timings. This demonstrates how much composite cables soften the dithering effect compared to "higher end" cables.

In the third and final example, composite cables are used, as well as the "Generic 4:3" H. Sampling preset, "Soft" Vertical Filter, "Consumer 1" Post-Processing preset, and Pre-Emph. set to "-5". These settings work to soften of the image, and in tandem with the RetroTINK-5X Pro's CRT filters might handle dithering in a way that is more pleasing to some users. Experimentation is encouraged to find your preferred look.

Note that any "CRT Filter" screenshots (such as the 3rd example image below) will not look correct unless opened and viewed at 100% size in your browser.

Dithering Reduction Example (Silent Hill for PlayStation 1)
Dithering - RGB Optimal	Dithering - Composite Optimal	Dithering - Composite W/ Post Processing

Discontinued Features

Because of limited memory capacity on the RetroTINK-5X Pro and evolving feature sets, some previously supported features have been discontinued. Thankfully, these features can be restored by rolling back firmware versions. Note that this wiki is designed to be up-to-date with the latest firmware revision, so rolling back might your firmware may alter functionality or remove features described in this document. User discretion is advised. More information about version differences can be found in the Firmware Notes and RetroTINK-5X Pro Firmware Version History Wiki.

4K24 Output

The experimental 4K/24Hz output mode was removed in version 2.98. The 1440p output mode has been retained (see below).

1080p (Min-Lag)

As of Firmware 2.98, the RetroTINK-5X Pro runs using the new RT4K buffer mode, which makes all output resolutions "min lag" mode. Thus, the original dedicated '1080p Min-Lag' mode was removed for redundancy.

540p Output Support

540p Output was a output resolution that catered to a common HD-CRT resolution. 540p Output was removed in firmware version 2.71

Chroma Mode Setting

Previously found in the [HDMI] menu, Chroma mode has been removed due to being a mostly unused debugging option. It was discontinued in firmware version 2.74.

1440p Output Visibility

While the 1440p output mode was not removed, its visibility is now hidden. To enable it, go to the [OSD] menu and set "Advanced Res" to Yes. This change was first applied in firmware version 2.71.

• REMINDER: Advanced Resolutions are hidden for a reason! They are provided without support or guarantees.

RetroTINK-5X Pro User Interface Map

RetroTINK-5X Pro Main Menu

Input Source

Output Resolution

Output Resolution (Advanced Res)

The following outputs are disabled by default and can be enabled by setting “Advanced Res” to “On” in the [OSD] (On-Screen Display) menu.

Scaling/Cropping

Interpolation/De-interlacing

Interpolation/De-interlacing	Description
Vertical Filter	Sharp: Uses a sharp interpolation method to generate the sharpest possible pixel edges. Medium: A somewhat softer option for less hard edges from pixel to pixel, akin to a "bilinear filtering" mode. Soft: Set to choose soft edges around the pixels, akin to a "bilinear filtering" mode. Smooth: A custom smoothing algorithm akin to a classic emulator "Super Eagle" mode.

Horizontal Sampling

Note for further explanation - The H. Interp takes the horizontal resolution produced by the ADC sample rate and the further interpolates it to the final display resolution.

Post-Processing

Standard Definition Decoder

Video ADC

HDMI Output

On-Screen Display

Save Profile

Load Profile

Status

About

The about page will display the following information as of the current firmware update:

RETROTINK-5X Pro
© 2021-2-22 RetroTINK LLC
All Rights Reserved
Need Help? Join the RetroTINK Discord!

Official User's Manual v1

A Wiki version of the official RetroTINK-5X Pro user's manual can be found here.