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Apple iPhone 14 Pro Max Display test

September 23, 2022
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146
display
This device has been retested in the latest version of our protocol. Overall, sub-scores and attributes are up to date. For detailed information, check the What’s New article
OTHER AVAILABLE TESTS FOR THIS DEVICE

We put the Apple iPhone 14 Pro Max through our rigorous DXOMARK Display test suite to measure its performance across six criteria. In this test results, we will break down how it fared in a variety of tests and several common use cases.

Overview

Key display specifications:

  • 6.7-inch OLED, ~88.2% screen-to-body ratio
  • Dimensions: 160.7 x 77.6 x 7.85 mm (6.33 x 3.06 x 0.31 inches)
  • Resolution: 1290 x 2796 pixels, (~ 460 ppi density)
  • Aspect ratio: 19.5:9
  • Refresh rate: 120 Hz

Scoring

Sub-scores and attributes included in the calculations of the global score.

Apple iPhone 14 Pro Max
146
display
Readability
139

164

Color
151

165

Video
146

165

Touch
158

164

DISPLAY
Position in Global Ranking
31st
1. Google Pixel 9 Pro XL
158
1. Google Pixel 9 Pro
158
3. Honor Magic6 Pro
157
4. Google Pixel 9
156
5. Samsung Galaxy S24 Ultra
155
6. Google Pixel 8 Pro
154
6. Samsung Galaxy Z Fold6
154
6. Samsung Galaxy S24+ (Exynos)
154
6. Samsung Galaxy S24 (Exynos)
154
10. Google Pixel 8
153
10. Vivo X100 Pro
153
12. Google Pixel 9 Pro Fold
152
13. Apple iPhone 15 Pro Max
151
13. Apple iPhone 15 Pro
151
13. Honor Magic V2
151
13. Honor Magic5 Pro
151
13. Honor 200 Pro
151
18. Apple iPhone 16 Pro Max
150
18. Apple iPhone 16 Pro
150
18. Samsung Galaxy Z Flip6
150
21. Honor Magic V3
149
21. Samsung Galaxy S23
149
23. Google Pixel 7 Pro
148
23. Huawei Pocket 2
148
23. Huawei Mate 60 Pro+
148
23. Huawei Mate 60 Pro
148
23. Samsung Galaxy S23 Ultra
148
28. Honor 200
147
28. Samsung Galaxy S23+
147
28. Samsung Galaxy A55 5G
147
31. Apple iPhone 14 Pro Max
146
31. Apple iPhone 14 Pro
146
33. Google Pixel Fold
145
33. Google Pixel 8a
145
33. Samsung Galaxy S24 FE
145
33. Vivo X Fold3 Pro
145
37. Oppo Find X7 Ultra
144
37. Samsung Galaxy Z Flip5
144
39. Asus Zenfone 11 Ultra
143
39. Huawei P60 Pro
143
39. Samsung Galaxy A35 5G
143
39. Xiaomi 14T Pro
143
43. Apple iPhone 16
142
43. Apple iPhone 13 Pro Max
142
43. Oppo Find N2 Flip
142
43. Samsung Galaxy Z Fold5
142
43. Xiaomi 14T
142
48. Apple iPhone 13 Pro
141
49. Apple iPhone 15 Plus
140
49. Apple iPhone 15
140
49. Honor 90
140
49. Samsung Galaxy S23 FE
140
49. Xiaomi 14 Ultra
140
54. Apple iPhone 14 Plus
138
54. Apple iPhone 14
138
54. Honor Magic4 Ultimate
138
54. Oppo Find X6 Pro
138
58. OnePlus Open
137
58. Oppo Find X5 Pro
137
58. Vivo X Fold
137
58. Xiaomi 14
137
62. Google Pixel 7
136
62. Honor Magic Vs
136
62. Motorola Edge 50 Neo
136
65. Apple iPhone 13
135
65. Google Pixel 7a
135
65. Samsung Galaxy S22 Ultra (Snapdragon)
135
65. Vivo X90 Pro+
135
65. Xiaomi Redmi Note 13 Pro Plus 5G
135
70. Huawei P50 Pro
134
70. Nothing Phone (2)
134
70. Samsung Galaxy S22+ (Exynos)
134
73. Huawei Mate 50 Pro
133
73. Samsung Galaxy Z Flip4
133
73. Samsung Galaxy S22 Ultra (Exynos)
133
73. Samsung Galaxy S22 (Snapdragon)
133
73. Vivo X80 Pro (MediaTek)
133
78. Asus ROG Phone 7
132
78. Samsung Galaxy S22 (Exynos)
132
78. Vivo X90 Pro
132
78. Xiaomi Mix Fold 3
132
78. Xiaomi 13
132
83. Samsung Galaxy S21 Ultra 5G (Exynos)
131
83. Sony Xperia 5 IV
131
83. Vivo X80 Pro (Snapdragon)
131
83. Xiaomi 13 Pro
131
87. Apple iPhone 13 mini
130
87. Google Pixel 6 Pro
130
87. Honor Magic4 Pro
130
87. Oppo Find X5
130
87. Realme GT 2 Pro
130
87. Samsung Galaxy Z Fold4
130
87. Samsung Galaxy S21 Ultra 5G (Snapdragon)
130
87. Samsung Galaxy S21 FE 5G (Snapdragon)
130
87. Vivo X70 Pro+
130
87. Xiaomi 13 Ultra
130
87. Xiaomi 12T
130
98. Samsung Galaxy A54 5G
129
98. Xiaomi 13T Pro
129
98. Xiaomi 13T
129
101. Oppo Find N2
128
102. Apple iPhone 12 Pro Max
127
102. Asus ROG Phone 6
127
102. Sony Xperia 5 V
127
102. Xiaomi 12T Pro
127
106. Asus Zenfone 10
126
106. Oppo Find X6
126
106. Sony Xperia 1 IV
126
106. Vivo X60 Pro 5G (Snapdragon)
126
110. Google Pixel 6a
125
110. Google Pixel 6
125
110. Honor 70
125
110. Oppo Find X3 Pro
125
110. Xiaomi Mi 11 Ultra
125
110. Xiaomi Mi 11
125
110. Xiaomi 12S Ultra
125
117. Apple iPhone 12 Pro
124
117. Motorola Razr 50
124
117. OnePlus 11
124
117. OnePlus 10 Pro
124
117. OnePlus 9 Pro
124
117. Oppo Reno8 5G
124
123. Motorola Edge 30 Pro
123
123. Oppo Reno8 Pro 5G
123
123. Oppo Find X3 Neo
123
123. Xiaomi 12 Pro
123
127. Apple iPhone 11 Pro Max
122
127. Motorola Edge 40 Pro
122
127. Nothing Phone(1)
122
130. Apple iPhone 12
121
131. Apple iPhone SE (2022)
120
131. Realme GT 5G
120
133. Fairphone 5
119
133. Xiaomi 12
119
135. Asus Zenfone 8
115
135. Oppo Reno6 5G
115
137. Realme GT Neo 2 5G
114
137. Samsung Galaxy A52 5G
114
139. Motorola Razr 40 Ultra
113
139. Oppo Find X5 Lite
113
141. POCO F4 GT
111
142. Crosscall Stellar-X5
109
143. Samsung Galaxy A53 5G
108
144. Sony Xperia 10 V
105
145. Sony Xperia 10 IV
104
146. Xiaomi Mi 10 Ultra
103
147. Black Shark 5 Pro
100
148. Vivo X80 Lite 5G
99
149. Samsung Galaxy A22 5G
82
DISPLAY
Position in Ultra-Premium Ranking
24th
1. Google Pixel 9 Pro XL
158
1. Google Pixel 9 Pro
158
3. Honor Magic6 Pro
157
4. Samsung Galaxy S24 Ultra
155
5. Google Pixel 8 Pro
154
5. Samsung Galaxy Z Fold6
154
5. Samsung Galaxy S24+ (Exynos)
154
8. Vivo X100 Pro
153
9. Google Pixel 9 Pro Fold
152
10. Apple iPhone 15 Pro Max
151
10. Apple iPhone 15 Pro
151
10. Honor Magic V2
151
10. Honor Magic5 Pro
151
14. Apple iPhone 16 Pro Max
150
14. Apple iPhone 16 Pro
150
14. Samsung Galaxy Z Flip6
150
17. Honor Magic V3
149
18. Google Pixel 7 Pro
148
18. Huawei Pocket 2
148
18. Huawei Mate 60 Pro+
148
18. Huawei Mate 60 Pro
148
18. Samsung Galaxy S23 Ultra
148
23. Samsung Galaxy S23+
147
24. Apple iPhone 14 Pro Max
146
24. Apple iPhone 14 Pro
146
26. Google Pixel Fold
145
26. Vivo X Fold3 Pro
145
28. Oppo Find X7 Ultra
144
28. Samsung Galaxy Z Flip5
144
30. Asus Zenfone 11 Ultra
143
30. Huawei P60 Pro
143
32. Apple iPhone 13 Pro Max
142
32. Oppo Find N2 Flip
142
32. Samsung Galaxy Z Fold5
142
35. Apple iPhone 13 Pro
141
36. Apple iPhone 15 Plus
140
36. Xiaomi 14 Ultra
140
38. Apple iPhone 14 Plus
138
38. Honor Magic4 Ultimate
138
38. Oppo Find X6 Pro
138
41. OnePlus Open
137
41. Oppo Find X5 Pro
137
41. Vivo X Fold
137
44. Honor Magic Vs
136
45. Samsung Galaxy S22 Ultra (Snapdragon)
135
45. Vivo X90 Pro+
135
47. Huawei P50 Pro
134
47. Samsung Galaxy S22+ (Exynos)
134
49. Huawei Mate 50 Pro
133
49. Samsung Galaxy Z Flip4
133
49. Samsung Galaxy S22 Ultra (Exynos)
133
49. Vivo X80 Pro (MediaTek)
133
53. Asus ROG Phone 7
132
53. Vivo X90 Pro
132
53. Xiaomi Mix Fold 3
132
56. Samsung Galaxy S21 Ultra 5G (Exynos)
131
56. Sony Xperia 5 IV
131
56. Vivo X80 Pro (Snapdragon)
131
56. Xiaomi 13 Pro
131
60. Google Pixel 6 Pro
130
60. Honor Magic4 Pro
130
60. Oppo Find X5
130
60. Samsung Galaxy Z Fold4
130
60. Samsung Galaxy S21 Ultra 5G (Snapdragon)
130
60. Vivo X70 Pro+
130
60. Xiaomi 13 Ultra
130
67. Oppo Find N2
128
68. Apple iPhone 12 Pro Max
127
68. Asus ROG Phone 6
127
68. Sony Xperia 5 V
127
71. Oppo Find X6
126
71. Sony Xperia 1 IV
126
73. Oppo Find X3 Pro
125
73. Xiaomi Mi 11 Ultra
125
73. Xiaomi 12S Ultra
125
76. Apple iPhone 12 Pro
124
76. Motorola Razr 50
124
76. OnePlus 10 Pro
124
76. OnePlus 9 Pro
124
80. Xiaomi 12 Pro
123
81. Apple iPhone 11 Pro Max
122
81. Motorola Edge 40 Pro
122
83. Motorola Razr 40 Ultra
113
84. Crosscall Stellar-X5
109
85. Xiaomi Mi 10 Ultra
103

Pros

  • Boosted outdoor performance, thanks to impressive brightness (measured at over 2000 nits) that improves readability and color rendering
  • HDR shows fine contrast tuning, close to the artistic intent, and indoor brightness (1090 nits) is suitable for enjoying HDR content
  • Almost no frame drops are visible when playing videos or when gaming

Cons

  • Viewed on angle, the color cast shifts to green, which impacts skin tone rendering
  • Touch interaction lacks smoothness when gaming
  • Some imprecise lighting transitions while watching video content

With the appearance of the iPhone 14 Pro Max, Apple continues to refine its flagship product, with the new device surpassing the performance of the iPhone 13 Pro Max in nearly every attribute.

The new model’s display is the brightest among all devices tested to date — over 2000 nits (measured), which means content is readable even under bright sunlight; moreover, the increased brightness also improves overall color rendering.

Although there was no significant improvement in handling SDR video content, whose brightness remains sometimes too low, the new iPhone shows advances in fine contrast rendering of HDR10 content, and has much better playback management than the 13 Pro Max.

As with Apple phones generally, the 14 Pro Max continues to show superior control of aliasing.  But when gaming, or watching movies, users might find the new notch design uncomfortably intrusive.

Test summary

About DXOMARK Display tests: For scoring and analysis in our smartphone and other display reviews, DXOMARK engineers perform a variety of objective and perceptual tests under controlled lab and real-life conditions. Note that we evaluate display attributes using only the device’s built-in display hardware and its still image (gallery) and video apps at their default settings. (For in-depth information about how we evaluate smartphone and other displays, check out our articles, “How DXOMARK tests display quality” and “A closer look at DXOMARK Display testing.

The following section gathers key elements of our exhaustive tests and analyses performed in DXOMARK laboratories. Detailed performance evaluations under the form of reports are available upon request. Do not hesitate to contact us.

Readability

139

Apple iPhone 14 Pro Max

164

Samsung Galaxy S24 Ultra
i
How Display Readability score is composed

Readability evaluates how easily and comfortably users can read still content (photos & web) on the display under different real-life conditions. DXOMARK uses its Display Bench to recreate ambient light conditions ranging from total darkness to bright sunlight. In addition to laboratory tests, perceptual analysis is also made in real-life environments.

Learn more about how we test display readability

The Apple iPhone 14 Pro Max is the brightest device tested to date, although the increased brightness is not available for all content. That said, the new device has a noticeable advantage over other phones in terms of outdoor readability. At its default settings, it is still not bright enough in low-light environments, but it has good smoothness when adjusting to different ambient lighting conditions, and shows better overall uniformity than its immediate predecessor.

Luminance under various lighting conditions

Although the iPhone has higher brightness than the Samsung, its contrast value is lower due to a less profound dark (28 nits for the iPhone versus 19 nits for the Samsung).

Contrast under various lighting conditions

Readability in a low-light (0 lux) environment
From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Samsung Galaxy S22 Ultra (Exynos), Oppo Find X5 Pro
(Photos for illustration only)


Readability in an indoor (1000 lux) environment
From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Samsung Galaxy S22 Ultra (Exynos), Oppo Find X5 Pro
(Photos for illustration only)


Readability in an outdoor (20 000 lux) environment
From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Samsung Galaxy S22 Ultra (Exynos), Oppo Find X5 Pro
(Photos for illustration only)


Readability in a sunlit (>90 0000 lux) environment
From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Samsung Galaxy S22 Ultra (Exynos), Oppo Find X5 Pro
(Photos for illustration only)

The notch of the iPhone 13 Pro Max generated some uniformity issues in the top part of the display. Now that Apple has switched to a punch hole notch on the 14 Pro Max, the uniformity considerably improved, as shown below.

Luminance uniformity measurement

This graph shows the uniformity of the display with a 20% gray pattern. The more visible the green color, the more uniform the display.

Color

151

Apple iPhone 14 Pro Max

165

Google Pixel 8
i
How Display Color score is composed

The color attribute evaluates the capacity of the device to accurately reproduce colors. The measurements taken are for fidelity, white point color, and gamut coverage. We perform color evaluations for different lighting conditions to see how well the device can manage color in the surrounding environment. Colors are measured using a spectrophotometer in a controlled lighting environment. Perceptual analysis of color rendering is against the reference pattern displayed on a calibrated professional monitor.

Learn more about how we test display color

The iPhone 14 Pro Max shows much better color uniformity than the 13 Pro Max. In low light, content on the 14 Pro Max takes on an orange cast; indoors, the new device’s color cast is a bit more neutral than its predecessor’s. And while skin tones are still a bit yellow when viewed outdoors, the 14 Pro Max’s rendering is better than the 13 Pro Max’s yellow-green skin tones under the same lighting conditions. On angle, however, the 14 Pro Max takes on a greenish cast that adversely impacts skin tone rendering.

White point under D65 illuminant at 1000 lux

The brightness boost allows the iPhone 14 Pro Max to present more lively colors with the right amounts of detail and shade, whereas the iPhone 13 Pro Max is a bit washed out and the Samsung Galaxy S22 Ultra (Exynos) loses all nuances.

Color rendering in sunlight (>90 0000 lux)
Clockwise from top left: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Oppo Find X5 Pro, Samsung Galaxy S22 Ultra (Exynos)
(Photos for illustration only)
Color fidelity measurements
Apple iPhone 14 Pro Max, color fidelity at 1000 lux in the sRGB color space
Apple iPhone 14 Pro Max, color fidelity at 1000 lux in the DCI-P3 color space
Each arrow represents the color difference between a target color pattern (base of the arrow) and its actual measurement (tip of the arrow). The longer the arrow, the more visible the color difference is. If the arrow stays within the circle, the color difference will be visible only to trained eyes.

Regarding color shift in angle, the iPhone 14 Pro Max is less performant than its predecessor. Not only is the shift more pronounced, as the iPhone 14 Pro Max is more orange to begin with, but colors also shift more rapidly. For example, at a 30° angle, the iPhone 14 Pro Max shifts towards green over 3 JNCD in some cases, while the shift for iPhone 13 Pro Max is around 2 JNCD, as you can see in the graphs below.

Color behavior on angle
Apple iPhone 14 Pro Max
Apple iPhone 13 Pro Max
This graph shows the color shift when the screen is at an angle. Each dot represents a measurement at a particular angle. Dots inside the inner circle exhibit no color shift in angle; those between the inner and outer circle have shifts that only trained experts will see; but those falling outside the outer circle are noticeable.
Color shift on angle

Top, on axis; above, on a 45-degree angle. From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Samsung Galaxy S22 Ultra (Exynos), Oppo Find X5 Pro. The iPhone 14 Pro Max has a visible slight greenish cast when viewed on angle.
(Photos for illustration only)
White spectrum with/without Blue Light Filter
Spectrum measurement comparison of a white web page with the Blue Light Filter on and off.

Video

146

Apple iPhone 14 Pro Max

165

Samsung Galaxy Z Fold6
i
How Display Video score is composed

Our video attribute evaluates the Standard Dynamic Range (SDR) and High Dynamic Range (HDR10) video handling of each device in indoor and low-light conditions. We measure tone mapping, color gamut, brightness and contrast of the display. We perform perceptual analysis against our professional reference monitor (Sony BVM-HX310) to ensure that the rendering respects the artistic intent.

Learn more about how we test display video

The Apple iPhone 14 Pro Max puts in a solid performance when handling HDR content, but its SDR video performance remains similar to that of the 13 Pro Max — that is, users may need to manually adjust the brightness to enjoy SDR content in a dark environment. But the 14 Pro Max’s improved contrast produces a rendering with more visible dark tones are more visible and natural highlights.

Although acceptable, the new iPhone’s color cast is less neutral (in other words, more yellow) that of the 13 Pro Max.

Video brightness at 10% APL in the dark ( < 5 lux)
Video rendering in a low-light (0 lux) environment
Clockwise from top left: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max, Oppo Find X5 Pro, Samsung Galaxy S22 Ultra (Exynos)
(Photos for illustration only)

The illustration below represents the brightness measurement (in false colors) of the same video played on the iPhone 14 Pro Max. The example on the left is HDR10, and the one on the right is SDR. The SDR-encoded video is too dark for the eyes, even on mid-tones, compared with the same video that is HDR-encoded. As a result, the user will have to manually adapt the screen brightness when switching between SDR video and HDR video content.

Apple iPhone 14 Pro Max HDR video, left; SDR video, right.

Clipping artifacts are visible in some videos, which results in a strong loss of detail, as can be seen when comparing the iPhone 14 Pro Max with its Samsung peer in the example below.

From left to right: Apple iPhone 14 Pro Max, Samsung Galaxy S22 Ultra (Exynos)
(Photos for illustration only)

The 14 Pro Max’s increase in brightness ensures a pleasant experience when viewing HDR content indoors, as you can see below. The iPhone measured over 1000 nits on a white HDR10 pattern versus 469 nits for the Samsung.

Video rendering in an indoor (1000 lux) environment
From left to right: Apple iPhone 14 Pro Max, Samsung Galaxy S22 Ultra (Exynos)
(Photos for illustration only)

The iPhone 14 Pro Max is capable of adapting its color gamut depending on the content you play. It matches the DCI-P3 gamut for HDR10 videos and the sRGB gamut for SDR videos well, ensuring pleasant color reproduction when watching videos (although True Tone sets a yellowish white point in a dark environment).

Gamut coverage for video content
HDR10 Gamut coverage
SDR Gamut coverage
The primary colors are measured both in HDR10 and SDR. The extracted color gamut shows the extent of the color area that the device can render. To respect the artistic intent, the measured gamut should match the master color space of each video.

Motion

Apple iPhone 14 Pro Max

i
How Display Motion score is composed

The motion attribute evaluates the handling of dynamic contents. Frame drops, motion blur, and playback artifacts are scrutinized using games and videos.

Learn more about how we test display motion

The iPhone 14 Pro Max’s control of frame drops is similar to that of the 13 Pro Max’s, with both devices recording only a small number of drops during testing. The new model has better video playback management than its immediate predecessor, and has good reactivity when jumping backwards or forwards.

Video frame drops
30 fps content
60 fps content
These long-exposure photos present the number of frame irregularities in a 30-second video. A good performance shows a regular pattern (either a flat gray image or a pull-down pattern).

Touch

158

Apple iPhone 14 Pro Max

164

Google Pixel 7 Pro
i
How Display Touch score is composed

To evaluate touch, DXOMARK uses a touch robot and a high-speed camera to play and record a set of scenarios for smoothness, accuracy and response-time evaluation.

Learn more about how we test display touch

The iPhone14 Pro Max’s touch response time is similar to the 13 Pro Max’s, albeit slightly slower, and the 14 Pro Max falls a bit behind the iPhone 13 Pro Max for smoothness when gaming.

Average Touch Response Time Apple iPhone 14 Pro Max
62 ms
Fast
Good
Bad
Slow
This response time test precisely evaluates the time elapsed between a single touch of the robot on the screen and the displayed action. This test is applied to activities that require high reactivity, such as gaming.

Artifacts

Apple iPhone 14 Pro Max

i
How Display Artifacts score is composed

Evaluating artifacts means checking for the performance, image rendering and motion flaws that can affect the end-user experience. DXOMARK measures precisely the device’s reflectance and the presence of flicker, and assesses the impact of residual aliasing when playing video games, among other characteristics.

Learn more about how we test display motion

The iPhone 14 Pro Max has a reflection rate of 5%, which is similar to the iPhone 13 Pro Max, but is far from the best performance in our database (measured at 4.2%).

Average Reflectance (SCI) Apple iPhone 14 Pro Max
5 %
Low
Good
Bad
High
SCI stands for Specular Component Included, which measures both the diffuse reflection and the specular reflection. Reflection from a simple glass sheet is around 4%, while it reaches about 6% for a plastic sheet. Although smartphones’ first surface is made of glass, their total reflection (without coating) is usually around 5% due to multiple reflections created by the complex optical stack.
Reflectance (SCI)
Measurements above show the reflection of the device within the visible spectrum range (400 nm to 700 nm). It includes both diffuse and specular reflection.
PWM Frequency Apple iPhone 14 Pro Max
480 Hz
Bad
Good
Bad
Great
Displays flicker for 2 main reasons: refresh rate and Pulse Width Modulation. Pulse width modulation is a modulation technique that generates variable-width pulses 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 the most extreme cases, can induce seizures. Some experiments show that discomfort can appear at a higher frequency. A high PWM frequency (>1500 Hz) tends to be less disturbing for users.
Temporal Light Modulation
This graph represents the frequencies of lighting variation; the highest peak gives the main flicker frequency. The combination of a low frequency and a high peak is susceptible to inducing eye fatigue. Displays flicker for 2 main reasons: refresh rate and Pulse Width Modulation. This measurement is important for comfort because flickering at low frequencies can be perceived by some individuals, and in the most extreme cases, can induce seizures. Some experiments show that discomfort can appear at a higher frequency. A high PWM frequency (>1500 Hz) tends to be safer for users.

Because of its new notch style, the Apple iPhone 14 Pro Max comes with an improved screen-to-body ratio; however, the big notch can be disturbing for some full-screen activities, such as watching movies, and some game apps have not yet adapted their content to the new notch.

Notch disturbance (video)
From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max
Notch Disturbance (gaming)
From left to right: Apple iPhone 14 Pro Max, Apple iPhone 13 Pro Max

The new device continues Apple’s tradition of having excellent control of aliasing.

Aliasing (closeup)
Apple iPhone 14 Pro Max

Apple iPhone 14 Pro Max – Crop 1
Apple iPhone 14 Pro Max – Crop 2
Apple iPhone 14 Pro Max – Crop 3

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