Jenoptik JD C 1.3 LCD vs. Panasonic Lumix DMC-LX100
Comparison
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Jenoptik JD C 1.3 LCD | Panasonic Lumix DMC-LX100 | ||||
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Megapixels
1.30
12.80
Max. image resolution
1600 x 1200
4112 x 3088
Sensor
Sensor type
CMOS
CMOS
Sensor size
1/2" (~ 6.4 x 4.8 mm)
Four Thirds (17.3 x 13 mm)
Sensor size comparison
Sensor size is generally a good indicator of the quality of the camera.
Sensors can vary greatly in size. As a general rule, the bigger the
sensor, the better the image quality.
Bigger sensors are more effective because they have more surface area to capture light. An important factor when comparing digital cameras is also camera generation. Generally, newer sensors will outperform the older.
Learn more about sensor sizes »
Bigger sensors are more effective because they have more surface area to capture light. An important factor when comparing digital cameras is also camera generation. Generally, newer sensors will outperform the older.
Learn more about sensor sizes »
Actual sensor size
Note: Actual size is set to screen → change »
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1 | : | 7.32 |
(ratio) | ||
Jenoptik JD C 1.3 LCD | Panasonic Lumix DMC-LX100 |
Surface area:
30.72 mm² | vs | 224.90 mm² |
Difference: 194.18 mm² (632%)
LX100 sensor is approx. 7.32x bigger than JD C 1.3 LCD sensor.
Note: You are comparing sensors of vastly different generations.
There is a gap of 12 years between Jenoptik JD C 1.3 LCD (2002) and
Panasonic LX100 (2014).
Twelve years is a huge amount of time,
technology wise, resulting in newer sensor being much more
efficient than the older one.
Pixel pitch tells you the distance from the center of one pixel (photosite) to the center of the next. It tells you how close the pixels are to each other.
The bigger the pixel pitch, the further apart they are and the bigger each pixel is. Bigger pixels tend to have better signal to noise ratio and greater dynamic range.
The bigger the pixel pitch, the further apart they are and the bigger each pixel is. Bigger pixels tend to have better signal to noise ratio and greater dynamic range.
Pixel or photosite area affects how much light per pixel can be gathered.
The larger it is the more light can be collected by a single pixel.
Larger pixels have the potential to collect more photons, resulting in greater dynamic range, while smaller pixels provide higher resolutions (more detail) for a given sensor size.
Larger pixels have the potential to collect more photons, resulting in greater dynamic range, while smaller pixels provide higher resolutions (more detail) for a given sensor size.
Relative pixel sizes:
vs
Pixel area difference: 6.16 µm² (35%)
A pixel on Jenoptik JD C 1.3 LCD sensor is approx. 35% bigger than a pixel on Panasonic LX100.
Pixel density tells you how many million pixels fit or would fit in one
square cm of the sensor.
Higher pixel density means smaller pixels and lower pixel density means larger pixels.
Higher pixel density means smaller pixels and lower pixel density means larger pixels.
To learn about the accuracy of these numbers,
click here.
Specs
Jenoptik JD C 1.3 LCD
Panasonic LX100
Total megapixels
16.84
Effective megapixels
12.80
Optical zoom
No
3.1x
Digital zoom
Yes
Yes
ISO sensitivity
100
Auto, 100 (extended), 200, 400, 800, 1600, 3200, 6400, 12800, 25600
RAW
Manual focus
Normal focus range
100 cm
50 cm
Macro focus range
20 cm
3 cm
Focal length (35mm equiv.)
46 mm
24 - 75 mm
Aperture priority
No
Yes
Max. aperture
f2.8
f1.7 - f2.8
Metering
Centre weighted
Multi, Center-weighted, Spot
Exposure compensation
±2 EV (in 1/3 EV steps)
±3 EV (in 1/3 EV steps)
Shutter priority
No
Yes
Min. shutter speed
1/4 sec
60 sec
Max. shutter speed
1/4000 sec
1/16000 sec
Built-in flash
External flash
Viewfinder
Optical
Electronic
White balance presets
6
5
Screen size
1.5"
3"
Screen resolution
921,600 dots
Video capture
Max. video resolution
3840x2160 (30p/24p)
Storage types
Secure Digital
SD/SDHC/SDXC
USB
USB 1.1
USB 2.0 (480 Mbit/sec)
HDMI
Wireless
GPS
Battery
4x AAA
Li-ion Battery Pack
Weight
110 g
393 g
Dimensions
97 x 28 x 63 mm
114.8 x 66.2 x 55 mm
Year
2002
2014
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Diagonal
Diagonal is calculated by the use of Pythagorean theorem:
where w = sensor width and h = sensor height
Diagonal = √ | w² + h² |
Jenoptik JD C 1.3 LCD diagonal
The diagonal of JD C 1.3 LCD sensor is not 1/2 or 0.5" (12.7 mm) as you might expect, but approximately two thirds of
that value - 8 mm. If you want to know why, see
sensor sizes.
w = 6.40 mm
h = 4.80 mm
w = 6.40 mm
h = 4.80 mm
Diagonal = √ | 6.40² + 4.80² | = 8.00 mm |
Panasonic LX100 diagonal
w = 17.30 mm
h = 13.00 mm
h = 13.00 mm
Diagonal = √ | 17.30² + 13.00² | = 21.64 mm |
Surface area
Surface area is calculated by multiplying the width and the height of a sensor.
JD C 1.3 LCD sensor area
Width = 6.40 mm
Height = 4.80 mm
Surface area = 6.40 × 4.80 = 30.72 mm²
Height = 4.80 mm
Surface area = 6.40 × 4.80 = 30.72 mm²
LX100 sensor area
Width = 17.30 mm
Height = 13.00 mm
Surface area = 17.30 × 13.00 = 224.90 mm²
Height = 13.00 mm
Surface area = 17.30 × 13.00 = 224.90 mm²
Pixel pitch
Pixel pitch is the distance from the center of one pixel to the center of the
next measured in micrometers (µm). It can be calculated with the following formula:
Pixel pitch = | sensor width in mm | × 1000 |
sensor resolution width in pixels |
JD C 1.3 LCD pixel pitch
Sensor width = 6.40 mm
Sensor resolution width = 1315 pixels
Sensor resolution width = 1315 pixels
Pixel pitch = | 6.40 | × 1000 | = 4.87 µm |
1315 |
LX100 pixel pitch
Sensor width = 17.30 mm
Sensor resolution width = 4126 pixels
Sensor resolution width = 4126 pixels
Pixel pitch = | 17.30 | × 1000 | = 4.19 µm |
4126 |
Pixel area
The area of one pixel can be calculated by simply squaring the pixel pitch:
You could also divide sensor surface area with effective megapixels:
Pixel area = pixel pitch²
You could also divide sensor surface area with effective megapixels:
Pixel area = | sensor surface area in mm² |
effective megapixels |
JD C 1.3 LCD pixel area
Pixel pitch = 4.87 µm
Pixel area = 4.87² = 23.72 µm²
Pixel area = 4.87² = 23.72 µm²
LX100 pixel area
Pixel pitch = 4.19 µm
Pixel area = 4.19² = 17.56 µm²
Pixel area = 4.19² = 17.56 µm²
Pixel density
Pixel density can be calculated with the following formula:
One could also use this formula:
Pixel density = ( | sensor resolution width in pixels | )² / 1000000 |
sensor width in cm |
One could also use this formula:
Pixel density = | effective megapixels × 1000000 | / 10000 |
sensor surface area in mm² |
JD C 1.3 LCD pixel density
Sensor resolution width = 1315 pixels
Sensor width = 0.64 cm
Pixel density = (1315 / 0.64)² / 1000000 = 4.22 MP/cm²
Sensor width = 0.64 cm
Pixel density = (1315 / 0.64)² / 1000000 = 4.22 MP/cm²
LX100 pixel density
Sensor resolution width = 4126 pixels
Sensor width = 1.73 cm
Pixel density = (4126 / 1.73)² / 1000000 = 5.69 MP/cm²
Sensor width = 1.73 cm
Pixel density = (4126 / 1.73)² / 1000000 = 5.69 MP/cm²
Sensor resolution
Sensor resolution is calculated from sensor size and effective megapixels. It's slightly higher
than maximum (not interpolated) image resolution which is usually stated on camera specifications.
Sensor resolution is used in pixel pitch, pixel area, and pixel density formula.
For sake of simplicity, we're going to calculate it in 3 stages.
1. First we need to find the ratio between horizontal and vertical length by dividing the former with the latter (aspect ratio). It's usually 1.33 (4:3) or 1.5 (3:2), but not always.
2. With the ratio (r) known we can calculate the X from the formula below, where X is a vertical number of pixels:
3. To get sensor resolution we then multiply X with the corresponding ratio:
Resolution horizontal: X × r
Resolution vertical: X
1. First we need to find the ratio between horizontal and vertical length by dividing the former with the latter (aspect ratio). It's usually 1.33 (4:3) or 1.5 (3:2), but not always.
2. With the ratio (r) known we can calculate the X from the formula below, where X is a vertical number of pixels:
(X × r) × X = effective megapixels × 1000000 → |
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Resolution horizontal: X × r
Resolution vertical: X
JD C 1.3 LCD sensor resolution
Sensor width = 6.40 mm
Sensor height = 4.80 mm
Effective megapixels = 1.30
Resolution horizontal: X × r = 989 × 1.33 = 1315
Resolution vertical: X = 989
Sensor resolution = 1315 x 989
Sensor height = 4.80 mm
Effective megapixels = 1.30
r = 6.40/4.80 = 1.33 |
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Resolution vertical: X = 989
Sensor resolution = 1315 x 989
LX100 sensor resolution
Sensor width = 17.30 mm
Sensor height = 13.00 mm
Effective megapixels = 12.80
Resolution horizontal: X × r = 3102 × 1.33 = 4126
Resolution vertical: X = 3102
Sensor resolution = 4126 x 3102
Sensor height = 13.00 mm
Effective megapixels = 12.80
r = 17.30/13.00 = 1.33 |
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Resolution vertical: X = 3102
Sensor resolution = 4126 x 3102
Crop factor
Crop factor or focal length multiplier is calculated by dividing the diagonal
of 35 mm film (43.27 mm) with the diagonal of the sensor.
Crop factor = | 43.27 mm |
sensor diagonal in mm |
JD C 1.3 LCD crop factor
Sensor diagonal in mm = 8.00 mm
Crop factor = | 43.27 | = 5.41 |
8.00 |
LX100 crop factor
Sensor diagonal in mm = 21.64 mm
Crop factor = | 43.27 | = 2 |
21.64 |
35 mm equivalent aperture
Equivalent aperture (in 135 film terms) is calculated by multiplying lens aperture
with crop factor (a.k.a. focal length multiplier).
JD C 1.3 LCD equivalent aperture
Crop factor = 5.41
Aperture = f2.8
35-mm equivalent aperture = (f2.8) × 5.41 = f15.1
Aperture = f2.8
35-mm equivalent aperture = (f2.8) × 5.41 = f15.1
LX100 equivalent aperture
Crop factor = 2
Aperture = f1.7 - f2.8
35-mm equivalent aperture = (f1.7 - f2.8) × 2 = f3.4 - f5.6
Aperture = f1.7 - f2.8
35-mm equivalent aperture = (f1.7 - f2.8) × 2 = f3.4 - f5.6
Enter your screen size (diagonal)
My screen size is
inches
Actual size is currently adjusted to screen.
If your screen (phone, tablet, or monitor) is not in diagonal, then the actual size of a sensor won't be shown correctly.
If your screen (phone, tablet, or monitor) is not in diagonal, then the actual size of a sensor won't be shown correctly.