We put the Motorola Razr 50 through our rigorous suite of SBMARK Display tests to measure its performance across four criteria. In this test results, we look at how it fared across a variety of tests and several common use cases.
Overview
Key display specifications
- 6.9 inch OLED
- Dimensions: 88.08 x 73.99 x 15.85 mm (3.47 x 2.91 x 0.62 inches)
- Resolution: 1080 x 2640 pixels, (~413 ppi density)
- Aspect ratio: 22:9
- Refresh rate: 120Hz
Pros
- Suitable for internal lighting environments
- Smooth visualization in every use case
- Uniform exposure
Against
- Colors appear too saturated using the default mode
- Too contrasty photos outside
- HDR10 videos too contrasty
The Motorola Razr 50’s display performance showed some improvement over previous-generation Razr models, but the flip phone lagged behind other foldable phones in our database.
Like other phones in this form factor, the Razr 50 falls into the ultra-premium category, even though it is priced at the low end of the segment.
The Razr 50 offered good screen brightness under challenging sunlight, and its screen brightness was also suitable for indoor environments despite having high reflectivity. Additionally, its viewing experience was very smooth in all the use cases tested, with the device showing very few frame drops.
The screen colors in the device’s default color mode were a bit too saturated in all lighting conditions.
Touch interactions were impacted by the significant delay in execution, with a measured latency of 100 milliseconds.
Test summary
About SBMARK Display Tests: For evaluation and analysis, a device is subjected to a series of objective and perceptual tests under controlled laboratory and real-life conditions. The SBMARK Display Score takes into account the overall user experience provided by the display, considering hardware capability and software tuning. Only factory-installed video and photo apps are used in the tests. More in-depth details on how SBMARK tests displays can be found in the article “A Closer Look at the SBMARK Display Tests”.
The following section focuses on key elements of our extensive testing and analysis in the SBMARK labs. Full reports with detailed performance evaluations are available upon request. To order a copy, please contact us.
How the display readability score is composed
Readability measures how easy and comfortable it is for a user to view fixed content, such as a photo or web page, on a display under different lighting conditions. Our lab measurements are complemented by perceptual testing and analysis.
Skin tone rendering in an indoor environment (1000 lux)
From left to right: Motorola Razr 50, Samsung Galaxy Z Flip6, Motorola Razr 40 Ultra
(Photo for illustration purposes only)
SCI stands for Specular Component Included, which measures both diffuse and specular reflection. The reflection from a simple glass pane is about 4%, while it reaches about 6% for a plastic pane. Although the first surface of smartphones is made of glass, their total reflection (without coating) is usually about 5% due to the multiple reflections created by the complex optical stack.
The average reflectance is calculated based on the spectral reflectance in the visible spectrum range (see graph below) and the human spectral sensitivity.
Uniformity
This graph shows the distribution of luminance across the entire display panel. Uniformity is measured with a 20% gray pattern, with bright green indicating ideal luminance. A bright green color evenly distributed across the screen indicates that the display is uniformly bright. Other colors indicate a loss of uniformity.
Displays flicker for 2 main reasons: refresh rate and pulse width modulation. Pulse width modulation is a modulation technique that generates pulses of variable width to represent the amplitude of an analog input signal. This measurement is important for comfort because flickering at low frequencies can be perceived by some individuals and, in extreme cases, can induce seizures. Some experiments show that discomfort can occur at a higher frequency. A high PWM frequency (>1500 Hz) tends to be less annoying to users.
How the displayed color score is composed
Color evaluations are performed under different lighting conditions to see how well the device handles color with its surroundings. Devices are tested with sRGB and Display-P3 image patterns. Both the true and default modes are used for our evaluation. Our lab measurements are complemented by perceptual tests and analyses.
Circadian clock factor is a metric that defines the impact of light on the human sleep cycle. It is the ratio of light energy that contributes to sleep disruption (centered at 450 nm, representing blue light) to light energy that contributes to our perception (covering 400 nm to 700 nm and centered at 550 nm, representing green light). A high circadian clock factor means that the ambient light contains strong blue light energy and is likely to affect the body’s sleep cycle, while a low circadian clock factor means that the light has weak blue light energy and is less likely to affect sleep patterns.
How the Display Video Score is Composed
The video attribute evaluates the Standard Dynamic Range (SDR) and High Dynamic Range (HDR10) video handling in indoor and low-light conditions. Our laboratory measurements are complemented by perceptual tests and analyses.
Video rendering in a low light environment (0 lux)
Clockwise from top left: Motorola Razr 50, Samsung Galaxy Z Flip6, Motorola Razr 40 Ultra
(Photo for illustration purposes only)
These indicators show the percentage of frame irregularities in a 30-second video. These irregularities are not necessarily noticeable to users (unless they are all in the same timestamp), but they are an indicator of performance.
How the Display Touch Score is Composed
We evaluate touch attributes across many types of content where touch is critical and requires different behaviors, such as games (quick taps for responsiveness), web (smooth page scrolling), and images (precise and fluid navigation from one image to another).
Start a new Thread