AV:RetroTINK-4K/ja

Raw IR Code 0xE51AB649 (NEC protocol) corresponds to address 0x49, command 0x1A.

• Because the video of Composite and S-Video is locked to 858 samples per line, no additional tweaking is required when using these input sources.
• Further, RoTATE mode will only work with 240p, 288p or 360p resolutions. This is important for titles that mix them with 480i.

If you're using RGB or YPbPr input, visit the RGB/Component ADC section of this page for information on ADC and decimation settings to meet the 1024 samples per line requirement. Similar limits apply when using HDMI® sources: use the Input Decimation settings in the "HDMI® Receiver" menu if the horizontal samples exceed 1024 (for example, MiSTer cores that use pixel repetition).

Auto Crop

The RetroTINK-4K can automatically crop and set aspect ratio for an input if it is fed a sufficient game screen. This feature works with RGB,Component and HDMI™ sources. Auto Crop looks for the black edges of a game image and crops to them, so use a picture that clearly shows the edges of the video for best results.

Screens that have any dark edges, as well as letterboxed, pillar-boxed, and window-boxed screens, are not recommended as they will fool the Auto Crop into thinking those are the edges of the image, resulting in an incorrect crop.

Scaler

The Scaler section in the RetroTINK-4K is where you'll find the tools that allow you to manipulate the geometry of the image.

Aspect Correction

The Aspect Correction setting chooses the Pixel Aspect Ratio, or "PAR", of the image. This is important because it needs to match the aspect ratio of the display the game is expecting to be seen on, referred to as the Display Aspect Ratio, or "DAR".

The Aspect Correction controls are only available when the current Input (analog or HDMI®) is a resolution with a variable PAR factor, such as 240p, 288p, 480i/p, and 576i/p. Most other resolutions will lock the Aspect Correction setting to their expected PAR, no matter the input. For example, 720p over the PS3's Component cables will lock Aspect Correction to "1:1 (Sq. Pixel)", while 480p over PS3's HDMI® cables will let you choose yourself. If the Aspect Correction controls are locked, you can still transform the image using the Scaling Factors tools.

The options that are available are:

If you're using a device that can use more than one Pixel Aspect Ratio, it's important that you set said device to correctly dovetail with the RT4K, so that the game will be shown correctly once it gets to your display.

Scaling Mode

Scaling Mode allows you to select automatic scaling modes or change aspect ratio constraints on manual scaling:

• Auto Fill - Fills the screen based on the selected Aspect Correction aspect ratio.
• Proportional - Allows the Vertical Factor to be adjusted while automatically adjusting the Horizontal Factor to keep the aspect ratio selected in Aspect Correction.
• Free-Form - Untethers the Vertical Factor and Horizontal Factor to allow values outside of the Aspect Correction setting. This setting lets you use the Vert. Factor and Hori. Factor settings to freely transform the image, like on the RetroTINK-5X.
• Auto Fill Integer - Scales the Vertical Factor and Horizontal Factor to the highest possible integer value without exceeding the screen boundaries, while also respecting the ratio selected in Aspect Correction. We highly recommend using the cropping tools to ensure the picture can be as large as possible while using this scaling mode.

Scaling Factors (Transform Tools)

The Horizontal Factor and Vertical Factor settings allow you to stretch and transform the image, either horizontally or vertically. Each factor diplays the multiplier value, the input resolution, and output resolution respectively.

Which of these are available depends on what option the Scaling Mode is set to. Proportional unlocks the Vert. Factor, while Free-Form unlocks both Vert. and Hori. Factors.

The function can be expressed as a simple formula: [Input Resolution] X [Multiplier] = [Output Resolution].

Buffer

The RetroTINK-4K allows users to set how much video to buffer before outputting to your screen. The buffer, in conjunction with the Sync Lock mode, are the main determining factors for overall latency.

• Min. Lag - Sets the buffer to only store to bare minimum number of video lines. This option provides the lowest latency.
• 1/2 Frame - Always buffers half a frame.
• 1 Frame - Always buffers a full frame.

Min. Lag is typically compatible, but if you encounter an edge case with screen tearing, try setting this to "1/2 Frame" or "1 Frame".

Certain movie modes, such as Inverse Telecine, will automatically force the RetroTINK-4K to buffer a full frame.

Masking Color

The masking colour settings allow you to adjust the colour of the mask that displays in the Scaling/Crop menu. By default, the values a 0 Red, 0 Green and 31 Blue. You can also change whether the masking colour is displayed in the cropping menu only, or always (even when the RT4K menu isn't displayed).

Processing and Effects

The Processing / Effects Setup menu is where you can adjust the pixel interpolation, as well as add Scanlines and CRT Masks.

Where are the Scanline Presets?

If you're a regular user of the RetroTINK-5X, you may be surprised to enter this menu and find that there's no Presets available to choose from. This is because they are stored as Profiles on the SD card.

• To load an included CRT Preset, head to the main menu, then go Profiles > Load from File > HDR CRT Simulation, then pick one you want to use.

The "bundling" of CRT Presets as Profiles may seem odd to users of the RetroTINK-5X (where CRT Presets could easily be applied to optimal sampling profiles), however this shouldn't have much impact on the final result. CRT displays are inherently a bit blurry as part of their aesthetic (even PVMs and BVMs), so generic sampling is perfectly acceptable to use for them. If you're using a digital source and decimating it (like Nintendo Switch Online or an HDMI® modded system), you may want to simulate the blur using the Horizontal Interpolation Kernel, and / or the Horizontal Blur function.

The only exception to the above is when you're using the LCD scanlines, as the thin lines dividing each pixel won't appear correctly without scaling the image up by a flat number (such as 4.000x or 5.000x).

Interpolation

Vertical and Horizontal Kernel

Interpolation in relation to video processing is a technique to create more visual information on the output that is given on the input. These processes help make a more visually cohesive image, and reduce effects such as shimmering when the image is scrolling. The RetroTINK-4K offers a handful of interpolation options that can be applied independently across the vertical and horizontal axis.

• Bilinear Sharp - The image is scaled up the maximum integer factor that is within the output size using Nearest Neighbor followed by a bilinear scale to the final output size. This option provides sharp pixels without shimmer at non-integer scaling factors.
• Bilinear Medium - The image is scaled up to the closest integer that is smaller or equal to the output pixels divided by 2 using Nearest Neighbor followed by a bilinear scale to the final output size. This option is somewhat softer than Bilinear Sharp but still sharper than regular Bilinear.
• Bilinear Std - The image is scaled using conventional bilinear filtering.
• Bilinear Soft - This performs linear interpolation over 4 pixels instead of the standard 2 pixels resulting in a very soft image. This may be desirable to produce horizontal blur for CRT effects
• Cubic - Interpolation using the bicubic spline kernel which outputs an image sharper than bilinear but softer than Lanczos.
• Lanczos2 and Lanczos3 - Interpolation using the Lanczos family of scaling algorithms. Lanczos is a popular algorithm that provides good results for natural imagery (i.e. movies) and most 3D games.
• None - The image is scaled using Nearest Neighborfor completely sharp pixels, but may shimmer if the Scaling Factors are not set to even multipliers (ie set to non-integer factors).

Anti-Ringing

Anti-Ringing is a toggleable option (On / Off) to reduce the appearance of ringing artefacts when using the Lanczos family of interpolation kernels. By default this setting is set to On, but even then it won't actually be engaged unless you're using Lanczos2 or Lanczos3.

Linear Light

Linear Light is a method of image color and brightness reproduction that may provide more accurate scaling and blending. Linear Light will also alter the appearance of scanline effects, which users may consider an improvement or not based on subjective preferences.

• Linear Light On - The RetroTINK-4K performs inverse gamma mapping at the start of the scaler pipeline and performs all operations in the linear light domain. The output is gamma encoded for SDR modes and PQ encoded for HDR modes.
• Linear Light Off - The RT4K performs all scaler operations in the gamma domain and only performs inverse gamma at the output if needed for color gamut transforms.

Assuming default SDR settings, for linear light to function properly, you have to manually set input factor and output factor to 2.4 in the Color Correction-> Gamma/PQ menu.
Enabling HDR in HDMI® Output->Transmitter, Enabling Color Space Conversion in Color Correction->Color Space Conversion, or Adobe RGB/P3 in HDMI® Output->Colorimetry will adjust Gamma/PQ settings by default to properly allow Linear Light processing.

More information on the benefits of linear light can be found here.

Scanlines

The RetroTINK-4K has customizable scanline generation which can recreate the look of various displays, including early LCD displays. Scanlines are an effect that simulates the appearance of blank scanlines on a display, similar to what you might see on older cathode ray tube (CRT) monitor or television screens. The effect creates generates black spaces between each visible scanline of video, simulating how lower resolution progressive signals would be presented on higher resolution (480i) displays.

Since scanlines are part of the image drawn by a CRTs red, green and blue electron gun, they scale with the image's pixels, and it's for this reason that the RetroTINK-4K's scanlines behave the same. This means that scanlines will appear thinner depending on the resolution of the input source; 240p scanlines are much thicker than scanlines placed on a 1080p input.

• For clarity, on a CRT, every line drawn on the display is a scanline. 240p however only uses half of these, resulting in blank scanlines every second row. This causes the scanlines to be perceptible, hence why these blank lines are called "scanlines" despite not being anything at all.
  
  

Proper simulation of CRT and LCD effects involves many more factors than just the scanline settings, such as but not limited to: Scaling, ADC Sampling, Interpolation / Filter and Color Correction. If this is overwhelming, please try one of the pre-made profiles first (included on the RetroTINK-4K SD card).

If your effects don't look correct on your display, your display may not be using 4:4:4 chroma. The methods of enabling this will vary, but solutions include enabling a setting on your TV such as Ultra Deep Color or changing the name and / or icon of the selected input to PC. If no solution is available, setting both the Vert. and Hori. Scaling Factors to even multipliers (such as 4.000x or 5.000x) may help.

Blank / Black Scanlines

This scanline function determines what formula is used by the scanline generator to translate the replaced video scanline to a "blank / black" scanline.

• Off - Disables the scanline generator. Further settings in the Scanlines section will not have an effect if Off is selected.
• Exponential - A scanline pattern that has the softest profile from bright to dark.
• Gaussian - A scanline pattern similar to Exponential, but with a sharper transition from bright to dark.
• Super Gaussian - A scanline pattern with a very sharp transition from bright to dark.
• Linear - A scanline pattern with a straight ramp from bright to dark.
• Box - A scanline pattern similar to old style emulator scanlines, with no blending from bright to dark. The scanline pattern is either completely on or completely off.

You can adjust the scanlines with the next settings:

• Strength - Adjusts the maximum width of the scanline effect.
• Modulation - Adjust how much the thickness of the scanline effect will change depending on brightness. Specifically, the higher this value, the thicker the black scanlines will be around dark areas of the picture.
• Pseudo Interlace - Draws scanlines with an interlaced order even if the source is progressive. 2x (i.e. 480p -> 960i) doubles the resolution so that no vertical detail is lost but results in thinner scanlines. 1x (i.e. 480p -> 480i) results in thicker scanlines but loses half the vertical resolution.

If you're inputting an interlaced signal, you should consider going to the Deinterlacer/Film menu and setting the Algorithm to "CRT Simulation". This will cause the scanlines to move up and down every frame, giving a look authentic to how these interlaced signals appear on a real CRT.

LCD Effects

The LCD functions behave differently than the "blank / black" functions, and are instead designed to simulate the appearance of older LCD displays.

• LCD Mono - Will place a 1x1 pixel border around every upscaled pixel in the image.
• LCD RGB - Simulates RGB subpixels per each upscaled pixel (similar to how the CRT masks simulate phosphor artifacts).

With LCD functions selected, the Strength and Modulation options change to "LCD Subpixel Str." and "LCD Vert Str.", respectively, and will retain their values. Despite being available for both LCD functions, they only have any effect on the LCD RGB effect.

• LCD Subpixel Str. - Sets how strong the LCD subpixel masking is. Lower values will more strongly "tint" the subpixels the colour of the upscaled pixel they represent.
• LCD Vertical Str. - Controls the size of the horizontal line under each pixel.

Color Bleed

Color bleed simulates some of the imperfections of how colors were presented on a CRT. These won't do anything unless a scanline generator is enabled; these won't work with the LCD effects.

• Red Bleed: Enabling Red Bleed simulates a common CRT effect where the Red beam is softer and less focused than Blue and Green.
• Red Convergence: Adjusts a vertical offset of the red data within the scanline effect. Can be adjusted from a -10 to 10 offset.
• Blue Convergence: Adjusts a vertical offset of the blue data within the scanline effect. Can be adjusted from a -10 to 10 offset.

Masks

Masks apply effects equivalent to the shadow masks on a CRT (as well as the similar aperture grilles and slot masks). Since these masks were metal plates that spanned the entire surface of a CRTs glass screen, they're independent of the image drawn by the red, green and blue electron guns. For this reason, masks on the RetroTINK-4K behave the same, and so will NOT adhere to the subpixels of the input you've selected.

The RetroTINK-4K accomplishes the mask effect by tiling an image across the entire screen at 1:1 sizing. Because of this, reducing the RT4K's output resolution will increase the size of the masks.

• Enable - Turns masks Off or On.
• Strength - Adjusts the strength of the masks. "+0" is the neutral value, "+10" is the maximum value, while "-10" is equivalent to turning Masks off.
• Load from File - Takes you to the "masks" folder of the SD card

If you want to make your own masks, head for the Custom CRT Masks section of this page.

Horizontal Blur

The Horizontal Blur function approximates the horizontal blurring present in some CRTs, looking rather like the right-to-left smearing on "3CHIP" Super Nintendos.

• Function - Can be set to "Off" or "IIR LPF".
• Cut-Off Freq - Adjusts the strength of the horizontal blur.

If you're wanting to blur the image in a more "traditional" sense, you'll want to use the Interpolation Kernels in the Processing/Effects menu.

Smoothing

Example 1: No smoothing Wxample 2 yes smoiot

The RetroTINK-4K offers an XBR-style smoothing algorithm to interpolate pixel edges for a smoother look. While intended for 2d-content, it can also help reduce visible aliasing with 3d content.

• Algorithm - Selects between "Off", "XBR Level 1", and "XBR Level 2".
• Noise Threshold - Selects between "Off", "Low", "Medium" and "High" settings.

Color Correction

Color Correction Example
Before Color Correction	After Color Correction
Golden Sun on Game Boy Advance / GBI Without Color Correction	Golden Sun using csc/Game Boy Interface/Game Boy Advance.txt

The Color Correction Setup menu controls the advanced color gamut correction and adjustment options on the RetroTINK-4K. The Apply Preset can be used to quickly load Color Correction profiles, such as the ones included on the 1.0 SD Card (more info on 1.0 CSC Profiles here).

Gamma and PQ

The input controls adjust how incoming RGB signals are converted from gamma space to linear light.

• Input Factor: Factor used to convert the input from gamma space to linear light. Input factor is the inverse gamma exponent. Can be adjusted between 0.10 and 5.00.
• Input Lift: Lift adds an offset (raises or lowers black level) to the input gamma conversion. Can be adjusted between -1.00 and 1.00.
• Input Gain: Gain multiplies the output of the input gamma conversion. Can be adjusted between 0.00 and 10.00.
• Output Factor: Available only in SDR, this is the factor used to re-encode the linear ligh output of the video pipeline back to gamma space. Can be adjusted between 0.10 and 5.00.
• SMPTE 2048 PQ: Available only in HDR, where the RT4K uses a perceptual quantizer instead of simple gamma, in order to tonemap the linear light signal into an HDR signal. The control sets the maximum brightness of the PQ in units of nits, which represents the maximum brightness of the tone mapping. Normally this is set to your TVs maximum nit level, however this function can be useful to dim the brightness of an HDR picture. Can be adjusted from 250 to 10,000.

Color Space Conversion

• Apply Preset: Opens the Load CSC Matrix menu, where users can load any saved CSC profiles from the SD card. Most use cases will involve simply applying a preset from the SD card, for example, to apply a color gamut correction to emulate a PVM. The RetroTINK-4K 1.0 SD Card release includes many presets.
  

You can explore the included CSC presets here.
Information on the Custom Color Matrix preset format can be found here.

• Custom Matrix: Allows the user to turn On or Off CSC by enabling/disabling the Input RGB to XYZ conversion matrix and settings applied to the Gamma/PQ.
• Prevent Clipping: Automatically scale the CSC matrix so that highlights are not lost at the cost of making the image dimmer. Can be set to On or Off.
• Saturation: Controls the color intensity. Lowering it turns the image black and white. Raising it makes the colors more intense. Can be set from -1.0 to +1.0.

Input RGB to XYZ

The user can manually adjust the matrix used to convert the input RGB data into XYZ colorspace. The RT4K automatically chains to correct conversion from XYZ to output RGB depending on the specified output colorimetry (e.g., BT709, BT2020, Adobe RGB, etc.). Each of the conversion functions can be adjusted between -1.75000 to +1.75000.

Advanced Controls

• Transfer Function: Can be set to "sRGB 0.055", "Rec.601/709 0.099", "SMPTE 240M 0.1115" or "Gamma". The various transfer functions linearize the low-end of the gamma curve to avoid bit loss. "Gamma" uses a simple gamma encoding.
• Bit Crush: Lowers the number of colors in the core video signal by reducing the number of bits per color. This is primarily intended for removing rounding errors that can occur in the original signal, e.g. when using GBI, as well as potentially removing noise in some limited cases. Alternatively, it can be used for aesthetic purposes to create a posterization or limited-color mode effect.
• Dithering: Can be set to "On" or "Off". Adds visually imperceptible random noise to the HDMI output to avoid banding and quantization artifacts due to the limit of 8-bit precision.

Black Frame Insertion (BFI)

BFI is for adding motion clarity. This does not interpolate frames like various settings on modern displays.

Please use caution when using BFI. This setting may not be great for people who are sensitive to strobing lights.

Black Frame Insertion (BFI) is a technique to improve motion clarity with high refresh rate monitors. As an example, a 60fps video source played on a 120hz monitor could have a black frame interstitially placed between every frame. The resulting "image-black-image-black" pattern can increase the perception of motion and fine details. If you have a higher refresh rate monitor, a customizable example can be viewed over at Blur Busters.

The use-case for Black Frame Insertion is to approximate the appearance of a CRT display, which would draw every line left-to-right, with the pixels dimming until they're replaced again for the next frame. Modern displays don't do this and never darken the pixels like this in the drawing process; this gives the effect of "blur" on moving parts of the picture. Black Frame Insertion is a crude but effective method of replicating the feel of looking at a CRT display, and gives the impression of better motion clarity.

BFI cannot be enabled unless the following two requirements are met:

• Set a supported Output Resolution and frame rate - Due to bandwidth constraints, BFI is limited to 1440p or lower resolution output. This also must be a high frame rate: either 100hz or 120hz.
• Set a supported Sync Lock Mode - BFI also cannot be enabled unless you are in Gen or Frame Sync Lock mode.

If both of these requirements are met, the BFI options will be unlocked.

• LCD Saver: LCD display panels may suffer from image retention when using BFI. The LCD Saver helps prevent this by inverting the order of (video frame)-(inserted frame) at the timer value set. LCD Saver can be set to 0, 1, 5, and 10 Minutes. When the frame order is inverted, it may create a momentary glitch in the video output. Note that setting the time value to 0 will display a message screen warning the user of possible LCD panel image retention.
• Min. BFI Limit: Can be set to "On" or "Off". Default "On". Disabling will disable safety limits for BFI strobe effects. Will prompt an additional warning screen when set to "Off".

BFI Control

Black Frame Insertion (BFI) Settings

Strobe: Strobe controls how the output frame rate is divided into the input frame rate. As depicted in the diagram, with Strobe 1, the 60Hz input frame is flashed one time at 240 Hz. At Strobe 2, the 60Hz input frame is flashed twice at 240Hz, with black frames in between. Alternatively, a 60Hz source within a 120Hz output would display for 1/2 of the time 120Hz output window. Blur: Blur is a duty cycle modifier that works in relation to Strobe to change how many frames the source video is presented in relation to the black frames. In the example diagram (60Hz Source inside a 240Hz output), a Blur of 1 would display the source video 1/4 of the 240Hz window, a Blur of 2 would display the source video 2/4 of the 240Hz window, and a Blur of 3 would display the source video 3/4 of the 240Hz window. Some relationships of Blur and Stobe are locked, such as a 60Hz video source in a 120Hz output window, which would only allow a Blur of 1 (1/2 of the output 120Hz window).

More information about BFI can be found at Blur Busters.

BFI Color

The BFI Color settings allows the user to change how the inserted frame appears.

The Blending Mode setting selects between the following functions:

• Solid: Creates a grayscale inserted frame that can be adjusted with any of the Red, Green or Blue BFI Color settings. A lower BFI Color numerical value is darker, higher is brighter.
• Alpha: In this mode, the inserted frame is a duplicated video frame with a transparent alpha overlay darkening the inserted frame based on the BFI Color setting. A lower BFI Color numerical value is darker/more opaque, a higher value is brighter/less opaque.
• Solid Color: Sets a solid inserted frame with an RGB-assignable color from the BFI Color selections.
• Alpha Color: Inserts a duplicated video frame with an alpha color overlay. The color of the alpha-blended frame is set from the R-G-B BFI Color values.
  

The Red, Green and Blue BFI Color values allow for customizable colors in the Solid Color and Alpha Color modes, and are an interlocked numerical valued for Solid and Alpha blending modes (R-G-B values cannot be adjusted separately).

Deinterlacer and Film

The Deinterlacer / Film Mode Setup menu allows you to adjust settings for use on interlaced sources, such as deinterlacing methods, apply LCD blending to progressive sources and setup Inverse Telecine.

While tweaking the options under the Mode and Motion Adaptive Settings sections, we suggest using the Pause Button to pause the video on a frame with motion. This will allow you to see the effects of the deinterlacing more easily.

Mode

There are six deinterlacing algorithms to choose from:

• Motion Adaptive - Uses an algorithm to determine whether to use Bob deinterlacing for areas of the screen that change, or Weave deinterlacing for areas that stay the same. Can be further tweaked in the Motion Adaptive Settings section.
• Weave - The current field remains on-screen while the next field is drawn, 'weaving' the two fields together. This is the same as 'disabled' in video players such as VLC, and will result in combing artifacts.
• Bob - Doubles the vertical height of each line to fill the full frame. This causes the image to appear as if it's moving up and down, since the two fields are not aligned in the interlaced signal, but preserves temporal resolution of interlaced video.
• Linear - Linear interpolated Bob (i.e., rather than a pure linedouble, line 2 is the average of lines 1 and 3, line 4 is the average of lines 3 and 5, etc.).
• Blend - The frame is created by averaging lines from the two most recent fields. Produces ghosting.
• CRT Simulation - Similar to Bob, but additionally changes scanline behavior to match that of interlaced content on a real CRT. If Scanlines have not been enabled, this mode will appear identical to Bob. See below for more details on this algorithm.
• LCD Blending - (Progressive sources) Averages the current frame and the previous frame. Produces ghosting that can blend flickering objects. (Interlaced sources) Averages the current field and previous same field, skipping the other field. Eliminates NTSC composite artifacts if the picture is completely still. Not recommended for gaming.

CRT Simulation

The CRT Simulation algorithm is unique enough to warrant its own section. It's used to to simulate the way 480i content is displayed on a real CRT: each frame of a 480i image is actually only 240 lines, and each new frame switches to using lines that were unused in the previous frame. Because of this, CRT Simulation will appear identical to Bob deinterlacing unless you use one of the Scanline functions enabled in the Processing / Effects menu (since they simulate the unused lines), and are viewing interlaced content.

CRT Simulation will also cause your crop settings to be displayed incorrectly, so be prepared to redo your crop after enabling this feature.

The output frame rate of the RT4K must match the input signal's frame rate in order for the effect to be displayed correctly. This is important if you're using a PAL system, which run at 50 frames per second: if the RT4K is outputting at 60fps (as it usually does by default), the CRT Simulation will not appear correctly for PAL content!

Motion Adaptive Settings

Motion Adaptive settings apply only to the Motion Adaptive Deinterlacing mode, allowing you to adjust how the Motion Adaptive Deinterlacing operates.

• Sensitivity: Adjusts the sensitivity of Motion Adaptive, between "Min", "Medium", "High" and "Max". The higher this is set, the more weaving will be present for moving parts of the screen, at the benefit of a stabler look for static parts of the screen. Many games will look just fine on the Min. setting, however several games may require Medium or higher. For example, Burnout 3: Takedown on PlayStation 2 has a subtle flickering and noise-like dithering that throws off the Motion Adaptive Deinterlacer for still parts of the screen.
• Noise Threshold: Adjusts how much low-level changes are ignored, so that the deinterlacer doesn't fall back to Bob deinterlacing unnecessarily. Useful for content that has noise and / or dithering present.
• Interpolator:Controls how the Bob function of the deinterlacer is calculated. The bob is either taken from the line above (Upper Field), line below (Lower Field) or the Average of the upper and lower lines.
• Detector: Can be set to "Zero-Lag", which favors the most current field. "Symmetric" favors the previous field, but allows for symmetric motion detection, which may provide cleaner results.

Bob Settings

The only Bob Setting here is the Bob Offset, which adjusts adjusts how far apart each field is from each other. It can be set between "-3" and "+3". This setting is useful for 240p games that were poorly ported to run at 480i, such as Mega Man Anniversary Collection on PlayStation 2.

Film Mode

The settings under Film Mode contain options to help process video content.

Inverse Telecine:

• 3:2 - In this mode, video content that was from a 24 Hz source converted to a 60 Hz signal will play back in a reconstructed 24 fps. This helps applicable video content play with its intended cinematic framerate.
• 2:2 - In this mode, the deinterlacer will rebuild progressive video output from 480i games that run at reliable/stable 30 fps, which effectively converts 480i into 480p. This will result in an increase in visual resolution and clarity. This is especially useful for PlayStation 2 where much of the library is 480i only.
  

Dejudder 24 Hz: This mode treats telecine material as a virtual 24 Hz source when using Gen Lock and Frame Lock Sync Lock, allowing for true 24 Hz output when combined with a 24 Hz output modeline. It can also be used with a 48, 72 or 120 Hz output modeline. This option only applies when a 3:2 source is successfully detected / deinterlaced.

Cadence Detection

The cadence detection menu offers controls to adjust the RetroTINK-4K's detection of content to pass to the the inverse telecine functions.

• Motion Digital, Motion CP, and Motion SDP: These values change the noise threshold for HDMI inputs, component/RGB inputs and composite/S-video inputs, respectively. Adjusting the noise threshold higher will decrease the detection of false positives, but may miss weaker or nosier telecine signals. Adjusting the threshold lower may increase false readings but allow less stable signals to be processed. Each value can be set from a range of 0 to 500.
• Threshold: Once a signal passes the check of the Motion thresholds, the Threshold number sets how many consecutive detections of a telecine pattern are required before the deinterlacer function activates. This may be helpful for noiser sources such as VHS to further filter out false detections.

HDMI® Receiver

The HDMI® Receiver Setup menu is where you control how the RT4K handles HDMI® In video. This menu is only functional when the HDMI® In port is the currently selected Input. If it is, this menu can be quickly accessed by pressing the ADC button at the top of the remote when HDMI® is selected as the input.

Input Decimation

Input Decimation

Input decimation is a function to reduce the horizontal resolution of a given HDMI input. This works by taking the current input horizontal resolution, and reducing it as a division between the Input Pixels and Output Pixels settings. A display of the final output resolution after decimation has occurred is shown in parenthesis at the end of the Input Pixels field. Input Pixels: Sets the number of sample width pixels to generate a decimation from. Output Pixels: Sets how many pixels to divide the sample width into. Initial Phase: Sets the phase offset for the decimation, determining which pixels are preserved and which pixels are removed.

Colorspace

Colorspace has options to assign what colorspace the HDMI® input is using, as well as what method to use for 4:2:2 upsampling.

• 4:2:2 Upsampler: Determines how to process digital inputs that are using 4:2:2 chroma subsampling. Can be set to "Linear", which uses a bilinear filter for a smoother appearance, or "Nearest", which uses a nearest neighbor filter for a sharper look (but with more obvious aliasing).
• Input Range: Determines what color range to process the incoming digital signal as. "Auto" should be used unless there is a specific colorspace mismatch. Other settings include "RGB Lim.", "RGB Full", "YCbCr 601", "YCbCr 709", "xvYCC 601", "xvYCC 709", "YCbCr 601 (Full)" or "YCbCR 709 (Full)".

This setting is independent of the HDMI range in the output menu. This should be consistent with the HDMI range of your console's output (e.g., the Wii U outputs Limited Range, so you set this to Limited Range, but you do not necessarily have to change the HDMI range in the output menu.

MiSTer DV1

Information about MiSTer DV1 goes here.

• Auto-Decimate: Can be set to "Infoframe", "Measure", or "Off".
• Auto-Crop: Can be set to "On" or "Off".

A/DAC

• A/DAC Mode: Allows Analogue consoles that support the Analogue DAC to output an unscaled image to the RT4K. For more information, please visit the Analogue Consoles section of the System Specific Settings page.
  • Off: The Analogue console sees the RT4K as a regular HDMI display.
  • NTSC: The Analogue console sees the RT4K as an Analogue DAC with the region switch set to NTSC.
  • PAL: The Analogue console sees the RT4K as an Analogue DAC with the region switch set to PAL.

PLEASE NOTE: While using A/DAC mode, the connected Analogue console will output 240p with horizontal variable pixel repetition, in order to allow for cases such as SNES 512-column mode to be rendered correctly. This may cause some scaling settings to not behave how you expect. Nothing is broken, please adjust Input Decimation and Scaling/Cropping until you get the desired image, noting that the initial horizontal scale is 4x what you are probably expecting (2x if you're playing a game that uses 512-column mode), and THIS MAY CHANGE IN THE FUTURE. Additionally, A/DAC Mode when set to PAL will require manual aspect ratio adjustment, and when set to either NTSC or PAL will require significant cropping when used with the Mega Sg due to the Mega Sg's output having a significantly exaggerated overscan area. Due to limitations both with Analogue hardware and with our understanding of the Analogue DAC, none of these issues can be addressed automatically at this time. Finally, please also note that, like with the actual Analogue DAC, changing the A/DAC mode setting while your Analogue console is connected and turned on will result in improper operation from your Analogue console, and is not recommended.

RGB and Component ADC

The RGB / Component ADC Setup menu is where you control how the RT4K handles analog inputs, such as the RCA, S-Video, HD-15 and SCART ports. This menu is only functional when an RGB or Component input is in use. If that is the case, this menu can be brought up by pressing the ADC button at the top of the remote when YPbPr, RGBS, RGsB, or RGBHV is selected as the input.

Sampling (ADC)

Sampling (ADC)

Samples per Line: Adjusts the total number of samples taken per line of video. When Samples per Line is set to a multiple of the pixels per line in a particular video source, the image will appear sharper as the pixel edge boundaries are aligned with the ADC sample rate. The parenthetical information after the Samples per Line shows the active, visible samples. Decimation Factor: Decimation divides the Samples per Line by the Decimation Factor value. For instance, if your Samples per Line is 1716, a Decimation Factor of 2 would leave 858 remaining samples. The parenthetical number after the Decimation Factor displays how many samples are remaining after decimation. Decimation Phase: Phase determines which set of samples is preserved when Decimation is active, and which set of samples is discarded. The selection will be a single instance of the Decimation Factor, I.E, If Decimation Factor was 3, you could choose between 1,2 or 3 Decimation Phase selections. Decimation Phase is disabled if Decimation Factor is off. Sub-Phase:A fine-tuning calibration to control the exact timing for when samples are taken. A calibrated Sub-Phase will result in a sharper image. This can be manually set or the alignment can be set with the Auto Phase function. Sub-Phase can be a value of 0 to 348.75 degrees, with 11.25 degree increment selections. Anti-Alias LPF: Applies a low pass filter the incoming analog signal before the signal is sampled by the ADC. This can help eliminate analog signal interference in the video, but may result in a less sharp image at higher settings. Auto setting will attempt to apply an appropriate setting based on the signal's sampling rate. Can be set to "Auto", "9MHz (Strong)", "16 MHz (Med)", "35 MHz (Light)", "95 MHz (Min.)" and "Off".

Sync (ADC)

• SoG Threshold: Sets the voltage level used to slice the video signal and generate a digital sync pulse. Adjusting this level may help with problematic sources. The voltage can be set between "0.00 mV" and "327.42 mV" in in 11.29 increments.
• Pre-coast: Sets the number of lines before vertical sync to switch from syncing with video source to internally generated sync. Can be set between 1 and 31 lines.
• Post-coast: Sets the number of lines after vertical sync to switch from syncing with video source to internally generated sync. Can be set between 1 and 31 lines.

The coast settings create a padding area away from the vertical sync pulse, so syncing to the horizontal doesn't encounter errors from off-spec signals or glitchy signal transitions. Adjusting Pre-coast and Post-cost values may be helpful when processing off-spec video sources.

• Wide Tolerance: Enables extra sync processing to help with 240p and 288p sources, such as arcade boards or NEOGEO, that may have sync issues due to malformed sync pulses. This should be turned off for normal use as it may cause artifacts for other systems.

Gain

• Pre-ADC: Changes the amount of analog gain applied to the signal before the ADC, functioning as a coarse contrast adjustment. Can be set between -0.7 and +0.8.
• Red,Green, and Blue allows fine adjustment of the individual color channel digital gain, functioning as a finer contrast adjustment per color channel. Can be adjusted between 1.000 and 1.996.

Offset

• Red,Green, and Blue offset provides per color black level / brightness adjustment. Values can be set between -100 and +100.

Auto Calibrate

Auto Phase

Any game screen is sufficient for automatic phasing, but it is recommended to use the 240p Test Suite or other sufficiently patterned screen for eyeballing results. whether you've set automatic sample detection using that menu, or you manually selected Decimation Factor in the ADC page, selecting Auto-Calibrate Phase makes the RetroTINK-4K automatically select the best Decimation Phase and Sub-Phase for your current picture and should give you the sharpest results. It is recommended you run this 3-5 times to make sure the same factors and phases are consistently chosen.

Auto Gain

The Auto Gain function will calibrate the gain levels for the current input, however it only works for RGB and YPbPr sources.

• To use Auto Gain, go to a game screen which has a patch of colour that should be pure white. When you enable the Auto Gain function, the RT4K automatically calibrates the Gain levels based on that white patch.

Auto Gain only works in calibrating the overall brightness Gain, not the individual color gain. You may need to manually adjust the individual colors a few ticks more for in the Gain section to get the true RGB code (255) for a given color. We highly recommend the use of the 240p Test Suite for this task.

Auto Gain must be calibrated on a per-console basis, meaning it will need to be set between different systems. This applies even across different units of the same system, such as two Super Nintendos, as their picture output will have degraded slightly differently.

Do NOT use this feature on Enhanced S-Video sources. The RT4K will try to calibrate Pb and Pr despite Enhanced S-Video's use of the SDP Decoder for color. Please calibrate gain on Green manually for Luma/Y only.

Sample Rate Detection

The Sample Rate Detection menu is where you control how the RT4K automatically detects the sample rate of a given analog source. This menu is only functional when an RGB or Component input is in use.

Sample Rate Detection Overview

The RetroTINK-4K can take advantage of sampling and scaling algorithms to seamlessly change settings when it detects a horizontal resolution change. This is useful for some analog retro gaming consoles, but requires knowledge of their "Master Sampling Rate." Please consult the table below to see which resolutions are available for consoles where automatic sampling detection is recommended.

If you do not see your console here, consider going to their System Specific Settings page and look for more information. Some consoles do not use this feature and will not be shown here.

Once you know the master sampling rate of your console, set that console's ADC Sample rate in the "Sample Rate Detection" menu under ADC Sample Rate, and turn both "Auto Dec. Factor" and "Auto Dec. Phase" to "On." Once you enable those options, if you know which resolutions you'll use, scroll down to that resolution to enable that horizontal resolution's detection and the RetroTINK-4K should automatically switch to a different set of settings whenever it detects that particular resolution is used. This process will help automatically set Decimation Factor and Decimation Phase in the ADC setup.

Control

• Auto Dec. Factor: Turns on Sample Rate Detection
• Auto Dec. Phase: Turning this on makes the RT4K select phase for you. This disables the Decimation Phase setting in the ADC menu.
• Detection Mode: Can be set to "Generic Console" or "Saturn". Generic Console covers most systems since they have a fixed video clock. A special Saturn mode is needed due to the Saturn's variable master video clock.
• ADC Sample Rate: Tells the RT4K how many samples to take in each line.

Progressive Detection & Interlace Detection

Each line shows the result of the ADC Sample Rate divided by a different Decimation Factor: 10, 8, 7, 6, 5, and 4, respectively.

SDP Decoder

The SDP Decoder Setup menu is where you control how the RT4K handles Composite and S-Video. This menu can be quickly accessed by pressing the ADC button at the top of the remote when S-Video or Composite are selected as inputs.

Gain and Balance

• Brightness: Adjusts the brightness of the image. Can be set between "-100" and "+100".
• Contrast: Adjusts the contrast of the image. Can be set between "-100" and "+100".
• Chroma: Adjust the saturation of the image. Can be set between "-100" and "+100".
• Phase: Adjusts the tint of the image.
• Blue Only: Displays a greyscale depiction of the blue colour values, with white being full blue and black being no blue.
• Setup: Can be set between 0 IRE and 7.5 IRE.

Processing

These controls will adjust how the RT4K handles the processing of the Composite video signal.

2D Processing

• 2D Y/C Filter: For composite video to be displayed, the "chroma" (color) and "luma" (black and white) parts of the signal must be separated. The RetroTINK-4K offers a variety of filter functions to perform this signal separation. The 2D functions available are "2D Adaptive", "2D Fixed" and "Notch".
• 2D Bandwidth: 2D bandwidth determines how much detail to try to preserve when separating luma and chroma components. Higher bandwidth maintains more detail but also introduces more artifacts. Can be toggled between "Low" and "High" settings.
• Chroma Bandwidth: Controls a low pass filter on the chroma signal, may help to remove rainbowing and other artifacts.
• Sharpness: Artificially sharpens the image. Can be set between "0" and "15".
• CTIE: Can be set between "0" to "3". CTIE sharpens the chroma channels using the luma channel as a guide.

3D Processing

• 3D Comb Enable: When set to "On", this will enable the RetroTINK-4K's 3D Comb Y/C Filter. The 3D Comb filter will analyze three consecutive fields of the same location in the video. If there is no detected motion across these 3 samples, the filter can operate with very high accuracy, effectively replicating the quality of S-Video. When changes across the sampled fields are detected, the algorithm will fall back to 2D Comb filtering, a technique that does not rely on previous frames of video to inform the filter. This "3D when the screen is still, 2D when in motion" is similar to the methods employed when using Motion Adaptive Deinterlacing. 3D Comb can be adjusted further with the Noise Threshold setting.
• Noise Threshold: Adjusts the 3D Comb sensitivity to bias 2D or 3D filtering. "Low" will quickly fall back to 2D filtering when motion is detected, while the Medium and High settings will bias the 3D filtering. "Default" is calibrated between "Low" and "Medium".

Sync (SDP)

Adjusts how the RetroTINK-4K syncs and locks onto the Composite signal.

• H-Lock Speed: Can be set to "Auto", "Slow", "Medium" and "Fast".
• Standard: Changes the analog signal standard for composite video decoding. Can be set to "Auto", "NTSC", "PAL", "SECAM", "NTSC-443", "PAL-M", "PAL-N" and "PAL-60".

Enhanced S-Video

Enhanced S-Video Example

S-Video	Enhanced S-Video w/ Optimizations

The RetroTINK-4K offers a special mode for processing S-Video (Y/C) video signals known as Enhanced S-Video. By bringing S-Video into the 4K's HD15 port, the signal can be fed through the SD and High-Resolution analog-to-digital converters simultaneously. This method offers higher resolution luma digitization, while enabling Decimation and Auto Phase on S-Video sources. To enable Enhanced S-Video, Y/C must be connected to the HD-15's Green/Red pins respectively, and the RetroTINK-4K's input must be set to Y/C on G/R (Enc.).

See Enhanced S-Video Wiring for more detailed information on how to bring S-Video into the HD-15 input.

• Chroma Shift: Adjusts the horizontal alignment of the chroma signal when using Enhanced S-Video mode. Can be set from "-100" to "100" Default is "0".

Audio Input

The Audio Input Setup menu is where you'll find options regarding the RT4K's handling of audio, such as the sampling rate and overriding which audio input is in use. More information can be found in the Alternate Audio Inputs and Inputs section.

Sampling (Audio)

• Sample Rate: Set the RetroTINK-4K's audio output sample rate. You can choose either 48khz and 96khz.
• Pre-amp Gain: Boost or attenuate the audio output gain. Can be set from -24dB to +28dB.

Source

• Input Override: Here you can override the current audio source with an alternate input, choosing between RCA, HD-15, SCART, Front S/PDIF or Off.
• Input Swap: Allows you to enable mono to stereo function (1 signal to two speakers) with Mono (left) and Mono (right) selections, or swap the left and right audio channels with the L/R Swap selection.

Surround Sound Input and Support

If your console is using Dolby Surround, it is likely using compressed surround sound encoded in Stereo Audio. There is no setting to adjust for this as it is entirely up to your receiver to decode Dolby Surround. The RetroTINK-4K simply passes this information through.

If your console outputs via Optical Audio, it will send compressed surround sound, which is properly decoded to the output.

If your console outputs LPCM via HDMI®, the RetroTINK-4K will simply pass through up to 8 channels of surround sound to its HDMI® output.

System

The System selection of menus relate to the RetroTINK-4K itself, including the On-screen display, firmware updates, and displaying various status screens.

OSD and Firmware

Banner Image

This menu allows you to load in your own banner. The default banner is the RetroTINK-4K banner, but community banners are also included, like FirebrandX's banner displaying Firebrand from Demon's Crest, and moon banners (which intentionally do not display the moon in a perfect circle).

Here's some information on how banners work on the RT4K:

• Banners are stored in the "image" folder of the SD card.
• Banners must be 24-bit BMPs in order to work with the RT4K.
• 320 x 128 is the recommended pixel dimensions. It can be larger, however only the upper-left 320x128 pixels of the image will be drawn.
• An RGB value of "255, 0, 255" (magenta colour) will be treated as transparency.
• Banners are saved as part of the profile.
• If a profile doesn't have a banner image specified, the file named "default.bmp" will be loaded instead. This lets you determine your own default banner image.

On Screen Display

This section allows you to adjust facets of the On Screen Display, including the menu.

• Position - This lets you set whether the menu is displayed on the Left side of the screen, the Center, or the Right side of the screen. This is set to "Left" by default.
• Auto-Off - Lets you determine how long the menu will wait before disappearing (as if you pressed the menu button). This is set of "Off" by default, but you can set it to turn the Menu off after up between 10 - 100 seconds (and anything in-between in 10 second increments).
• Hide Input Res. - Turning this on will mean the RT4K will not display the current input and resolution in the top-right corner of the screen every time it changes. This is useful if you're capturing or streaming games that switch resolutions.
• Enable Debug OSD - This option allows you to permenantly display one of the three Status Pages or the Diagnostic Console.

Firmware Update

This option allows you to Check the SD card for the two files needed for installing new firmware to the RetroTINK-4K. For more information on how to install new firmware, head to the Firmware Updates section.

Status

Displays the Status menu, letting you learn more about the current status of the RetroTINK-4K. For more information, visit the Device section of our GUI Map.

Diagnostic Console

Shows the 30 most recent actions in the RetroTINK-4K's operations. Or something?

About

Displays the About Page, containing the following information:

• About
  • Device - Displays information about the RT4K's hardware version.
  • FW Version - Displays the current firmware name.
  • Device ID - Displays the ID of the RT4K.
• Resources
  • Website - www.retrotink.com
  • Discord - discord.gg/jE6deAhjCM
  • Wiki - consolemods.org/rt4k
• Special Thanks To:
  • RetroRGB - GameSack - FirebrandX - Wobbling Pixels - Extrems - CouryC - John Linneman - Try4ce - Artemio - Blur Busters - Voultar - Old Kid - MinotaurZombie - teen Nick - Chungo - Mr. Moro - Guspaz - SquidHominid - Mizox - blizzz - Supercowabunga - Jeff Chen - pram0d - atrac17 - Cyo - 8bitesquire - Fenris Wolf Retro - Ace - Kuro Houou - ScarletSprites - wizzo - CGQ - TechnicalMonkey - EposVox - Derf - IceStrike256 - RegentOfOrigin - Kjeld - cobhc - KBABZ
    • Names are ordered to favour formatting, and are otherwise in no particular order.
      

SD Card and Profiles

The RetroTINK-4K includes an SD card with a set of Profiles, CRT Masks, Color Correction Profiles and more from the talents of FirebrandX, Wobbling Pixels, Exrems, Kuro Houou, pram0d, Cyo, MrMoro, austinbroth, Chungo, and (anyone else I'm forgetting). This area includes a mirror to download the stock RetroTINK-4K 1.0 Full SD Card, as well as a comprehensive list of every profile included with the release.

New SD cards, firmware, and profiles are now available in the Firmware Repository.

System Specific Settings

System Specific Settings is all about highlighting how you can use the RetroTINK-4K's various features to improve the experience of using your video game systems beyond just plugging them in. This can range from setting 1:1 pixel aspect ratio for Super Game Boy on the SNES, to dovetailing with the Sharpscale Plugin on the PlayStation TV.

• Due to its sheer size, this section has been broken out into its own subpage, which can be found here.
  

Additional Guides

Custom CRT Masks

The RT4K allows for the use of custom CRT Mask overlays via the Masks menu. This is primarily intended to give an effect similar to CRT shadow, slot and aperture masks that stretch across the screen (as opposed to scanlines, which affect the picture underneath). The RT4K uses mask images and tiles them across the screen to replicate the effect.

• To easily make your own CRT Mask, we recommend using infinest's Mask Editor tool.

Here's what you need to know when it comes to making your own CRT Mask:

• Custom CRT Masks must be saved as 32-bit .BMP files.
• The maximum dimensions of a CRT Mask image is 16 x 16 pixels. They can be smaller, which will result in denser tiling of the mask across the screen.
• A color value of 128 will be neutral, while 0 will completely black out the corresponding pixel. 255 will double the input value (although this will be clamped).
• Custom CRT Mask images should be stored in the "mask" folder on the SD card.

CRT masks will NOT adhere to the pixel grid like the RT4K's scanlines will. If you want them to adhere to the pixel grid, you'll need to have your shadow mask image match the dimensions of a single upscaled pixel, but this will vary depending on many factors, and so should be paired with a specific Profile you have in mind. Since Mask images have a maximum size of 16x16 pixels, this inherently means that the upscaled pixels of the input image cannot exceed 16x16 pixels in RT4K's output resolution.

Custom Color Matrix

RetroTINK-4K Custom Color Matrix Instructions - Custom color gamut correction factors can be loaded by the user. Each file is a set of csv values describing gamma and Input RGB -> XYZ transforms. The RT4K will automatically apply the correct XYZ -> Output RGB matrix depending on the specified HDMI output colorimetry.

The csv file has 14 entries (all floating point) on a single line:

• 1: Input Gamma
• 2: Input Lift
• 3: Input Gain
• 4: Output Gamma
• 5: Transfer Function (0 = sRGB, 1 = Rec. 601/709, 2 = SMPTE 240, 3 = Conventional Gamma)
• 6-14: Input RGB -> XYZ Matrix Coefficients

Thanks to Dan Mons, Keith Raney (https://github.com/danmons/colour_matrix_adaptations/tree/main) and Extrems (https://www.gc-forever.com/wiki/index.php?title=Game_Boy_Interface) for providing technical assistance and example data.

Custom Modelines

The RetroTINK-4k supports user generated modelines for custom output resolutions, these are accessible by the RES1-RES4 buttons directly on the remote control.

These can be edited on the SD card in the modelines folder, these are named custom1.txt, custom2.txt, custom3.txt, and custom4.txt (corresponding to the remote buttons)

Modelines are stored as a single line of 12 comma seperated values. For example:

1690, 130, 184, 624, 1, 1420, 3, 10, 60, 1, 69.420, "1420p60"

• 1. Horizontal Active Pixels
• 2. Horizontal Front Porch Pixels
• 3. Horizontal Sync Pixels
• 4. Horizontal Total Blank Pixels (Active + Front Porch + Sync + Back Porch)
• 5. Horizontal Sync Polarity (1 = positive, 0 = negative)
• 6. Vertical Active Lines
• 7. Vertical Front Porch Lines
• 8. Vertical Sync Lines
• 9. Vertical Total Blank Lines (Active + Front Porch + Sync + Back Porch)
• 10. Vertical Sync Polarity (1 = positive, 0 = negative)
• 11. Nominal Frame Rate (floating point value) when in Triple Buffer mode
• 12. String Text Name (not used currently)

To easily make your own custom modelines, we recommend using Guspaz's RetroTINK 4K Video Timings Calculator.

For example, users of 1536p displays like the iPad lcd monitors can use the following modeline:
2048, 48, 32, 160, 1, 1536, 3, 4, 44, 0, 60.0, "1536p"

Custom Modelines Tutorial

This is not an exact science. There are many variations of modelines and display technologies, and your particular display may not agree with the modeline you are trying to feed it, despite timings falling under 600MHz and your display's feature claims. Unfortunately every combination of display and modeline cannot be tested by Mike alone and we depend on the community to help give information regarding modelines and particular displays.

Follow these steps to correctly use the Custom Modelines Feature. For this example a 1080p180 modeline will be used for a monitor that cannot reach 240fps, but a 2-1 BFI cadence is still possible.

1. Find the resolution and framerate of your display. For this example: 1920x1080p is the resolution and 180fps is the framerate.
2. Visit the RT4K Video Timings Calculator
3. Enter your desired Horizontal Pixels, Vertical Pixels, and Refresh Rate (Hz). In this example, 1920 goes into horizontal pixels, 1080 goes into vertical pixels, and 180 goes into the refresh rate.
4. Click into another field to update the Timings chart.
5. Note that the Timings chart will show some values in green and some values in red. Green Values indicate the timing is within the 600MHz output clock of the RT4K. Red means the timing exceeds the 600MHz output and the RT4K will not work with it.
6. Make your way down to "RT4K Custom modelines" and note the text for the modelines that are green. In this example you want the following bits of text
   • 1920, 176, 208, 768, 0, 1080, 3, 5, 122, 1, 179.98, "1920x1080p179.98"
   • 1920, 48, 32, 160, 1, 1080, 3, 5, 98, 0, 179.98, "1920x1080p179.98"
   • 1920, 8, 32, 80, 1, 1080, 84, 8, 98, 0, 180, "1920x1080p180"
   • 1920, 8, 32, 80, 1, 1080, 84, 8, 6, 0, 180, "1920x1080p180"
7. Take your SD Card out of your RT4K and connect it to your computer. Enter the "modelines" folder in the root of your SD Card. You should note there are 5 files: "_Mode Line Instructions.html" has the information noted in the above section. "Cutom[number].txt stores modeline data.
8. Open each modeline file and put one modeline noted above into each file. If you have more than 4 you will have to come back to this step, as the RT4K can only use 4 at a time.
9. Save each file. Place your SD Card back into your RT4K.
10. With your RT4K on, press the Res1, Res2, Res3, and Res4 on the remote until you find a modeline that is stable.
11. You may have to repeat this tutorial and tweak your values until you find something your display agrees with. As an example, a 180Hz modeline may not work with a Super NES, which would need a Refresh Rate of 180.03Hz for its unique refresh rate.

Custom Input Modes

Custom input mode definitions improve the handling of input sources that are detected as "Unknown" by the RetroTINK-4K. Unknown input sources are often displayed as a small strip in the middle of the screen, with parts of the image missing. With the correct definition the image will be automatically cropped and scaled to the desired aspect ratio. Up to 24 definitions can be added to the "input_database.txt" text file in the "inputmodes" folder on the SD card.

The parameters for each custom input mode is a single line of csv values with the format: 1. Minimum acceptable frame rate (floating point)
2. Maximum acceptable frame rate (floating point)
3. Minimum acceptable number of lines per frame (integer, note interlaced signals are treated on a frame, not field basis, so 525 for 480i or 625 for 576i)
4. Maximum acceptable number of lines per frame (integer)
5. Horizontal Sync Polarity (integer, 0 = don't care, 1 = negative, 2 = positive)
6. Vertical Sync Polarity (integer, 0 = don't care, 1 = negative, 2 = positive)
7. Interlaced (integer, 0 = expect progressive, 1 = expect interlaced) 8. Horizontal Sync + Back Porch Pixels (integer)
9. Horizontal Active Pixels (integer)
10. Horizontal Total (Front Porch + Sync + Back Porch + Active) Pixels (integer)
11. Vertical Sync + Back Porch Lines (integer)
12. Vertical Active Lines (integer)
13. Vertical Total (Front Porch + Sync + Back Porch + Active) Lines (integer)
14. Actual Horizontal Sampling Pixels (integer)
15. PAR Factor (float) 16. Desired Slot Number in Profile (integer 1-24)
17. String Name for Mode

If an RGB or YPbPr signal does not match an existing known definition, the RT4K will attempt to find a match from the database file using parameters 1-7. If a match is found, parameters 8-15 are then used for sampling and cropping the signal. The save slot inside the profile file that is used for this custom input mode is set by parameter 16. The final parameter is the name for the custom input mode, which is shown in the RT4K menu and input detection popup.

Examples:

This is the input mode definition for a standard 480i signal: "55.0, 65.0, 523, 527, 0, 0, 1, 122, 720, 858, 18, 240, 263, 1716, 0.90909, 10, 480iCustom"

Input mode defintion for Sega NAOMI provided by Aru: "59.0, 61.0, 529, 531, 1, 1, 0, 122, 749, 858, 34, 480, 495, 2200, 0.90909, 11, Sega Naomi"

Notes:

• Parameters 8-13 can be determined either from technical documentation of the source system, or by trial and error.
• The actual sample rate (parameter 14) can be different from the "canonical" sample rate (item 10) for the input mode.
• BT.656 480i signals are conventionally sampled with 858 pixels/per line with a PAR of 10/11 (0.9090). However, the modeline specifies that the RT4K should actually sample at 1716 pixels per line (which will result in improved image quality due to oversampling). The RT4K will use the "canonical" sample rate, the PAR factor and the actual sample rate such that the final image is scaled correctly.

Preparing your TV for use with the RT4K

Try these options to prepare your TV for use with the RT4K. You may need to do a google search for [your tv model number] and the setting you are looking for, as every manufacturer uses a different name for the feature.

• Turn off Motion Interpolation. This is a very big contributor to latency. Disabling this also helps make sure post processing effects render correctly
• Turn off every setting if it has an off switch. Smart TV settings typically add to latency.
• Turn on Game Mode. This helps turn most off most options, but you may need to manually turn off other settings. Game mode should instruct the display to let the RT4K drive the display rather than letting the display dictate how to handle colors and effects. Turning game mode on is usually the best way to lower latency.
• Turn on PC Mode. This typically forces the PC to display all colors and disables chroma subsampling on a TV. PC mode on and off is the difference between post processing effects looking correct and not rendering correctly. See below for an example.
• Locate your TV's Black Frame Insertion feature. If your TV has BFI you may want to implement that while the RT4K renders in 4K to reap the benefits of 4K post processing and keeping your resolution high.
• Enable HDR and make sure all previous steps are repeated. Some displays will turn previously unselected options back on when you enable HDR.

Community Resources

This section provides a list of helpful resources and additions to the RetroTINK-4K. Click the link in the name to go directly to an item's page.

Accessories

Downloads and Web Pages

Various downloads and websites for use with the RT4K, including 3D printed files and custom modelines.

Community Profiles

Helpful Profiles created by the RetroTINK-4K community. These are not contained on the SD Card by default: to add them, connect the RT4K's SD card to your computer, then drag the profile's .rt4 file into the "profile" folder on the SD card.

All community profiles can now be found on the firmware repository. These are rounded up and released with every stable firmware release. https://retrotink-llc.github.io/firmware/4k-sdcards.html

Community Masks

Comunity masks can be found in the SD Card Images on the Firmware Repository under Masks.

Community Banners

Banners made by the RetroTINK-4K community. These should be placed into the "banners" folder on the SD card. Refer to the OSD and Firmware section for more information on how to select a banner for your profile.

Preview	Name	Author(s)	Description
	MiSTerFPGA	Pezz82	The MiSTer FPGA logo, as a banner!
	RT4K-RGB	ArielAces	Rainbow RGB banner of the RetroTINK-4K logos.
	Retrowave	ArielAces	A Retrowave-style RetroTINK-4K banner.
	NES-SMB3	ArielAces	A banner styled after the NES and Super Mario Bros. 3.
	SNES-SFII	ArielAces	An SNES Street Fighter II banner.
	Chrono Trigger	ArielAces	A Chrono Trigger-themed banner.
	Sega Sonic A	ArielAces	A Sonic the Hedgehog-themed banner.
	Sega Sonic B	ArielAces	A banner themed after the Sonic the Hedgehog logo. Ooo!
	#EmulationIsForQuitters	ArielAces	A banner made for 8BitEsquire after his Emulation is for Quitters hashtag.
	$10 FPGA inside	ArielAces	A banner made for 8BitEsquire after the $10 FPGA in-joke in the RetroTINK community.
	RetroRGB	ArielAces	A banner made for Bob from RetroRGB after said website.
	The Lag is Real!	ArielAces	A The Lag is Real! banner made for Bob from RetroRGB. Features the faces of Bob and Art of fgcOS.

Video Guides

Various videos that help with using the RetroTINK-4K.

Other Resources

For other cool things that don't really fit anywhere else.

Item	Author(s)	Description
	Mike Chi	The image used for the sticker on the SD Card that comes with every RT4K.

FAQ / Troubleshooting

Support Questions

Basic Troubleshooting Steps

Confirm the following

• Your power supply is capable of 5V and at least 2A (or 5V and at least 10W)
• SD Card is formatted with FAT32
• Input is 1080p60 or less
• Correct input is selected on the RetroTINK-4K to match your device. Confirm by cycling through the variations on the Input menu at the top of the RetroTINK-4K menu
• Output cable is rated for HDMI 2.0 (18Gbps). Narrow down to this or display support issue by using 480p button on bottom half of remote
• Your display supports 4K. Narrow down to this or HDMI issue by using 480p button on bottom half of remote
• Motion Interpolation is off. Called different things by different manufacturers (Motion Smoothing, Tru(e) Motion, etc.), this creates extra frames that aren't present in the source and can cause flickering or ghosting, especially when using scanlines. Check your TV's manual for how to disable this feature
• Chroma Subsampling is set to 4:4:4 (often incorrectly called "RGB"), instead of 4:2:2. When incorrectly set colors may distort and fine details may be lost. This can be set on many displays by setting the input to "PC Mode". Check your TV's manual for how to enable this feature

Try this

• Connect your console directly to the RetroTINK-4K and the RetroTINK-4K directly to your Display without splitters (unless absolutely necessary), AVRs, etc.
• Download the newest stable firmware and put BOTH files on the root of the SD card (overwriting anyrt4kup.bin file that already exists). Hold the reset button on the back of the device as you plug in the device or press the power button on the remote. Wait for it to update.
• Reload the profile you were using to reset any changes. Download it again if needed. Reload the default if you're too far gone.
  

Store / Pricing Questions

Compatibility Questions

Hardware Questions

Software Questions

Comparison Questions

Recommendation Questions

Miscellaneous Questions

RetroTINK-4K GUI Map

The GUI Map lists every single menu and menu item on the RetroTINK-4K, along with a brief description of what it does. For more information on them, click on a header to be taken to the appropriate section on this page.

GUI - Basic Setup

GUI - Input Selection

More information concerning inputs can be found in the Inputs section.

GUI - HDMI® Output

More information concerning outputs can be found in the Outputs section.

GUI - Profiles

GUI - Advanced Settings

GUI - Scaling/Cropping

GUI - Processing / Effects

GUI - Color Correction

GUI - Black Frame Insertion

GUI - Deinterlacer / Film

* Works with progressive inputs.

GUI - Acquisition

GUI - HDMI® In Receiver

GUI - RGB / Component ADC

GUI - Sample Rate Detection

GUI - SDP Decoder

GUI - Audio Input

GUI - System

GUI - OSD / Firmware

GUI - Device

GUI - Status

GUI - System Status Page 1

GUI - System Status Page 2

GUI - System Status Page 3

GUI - Diagnostic Console

GUI - About