All dimensions (width, height, and depth) are rounded to the closest millimeter in this table. As a starting point for the comparison, the following is a high-level summary of the major specifications of the two cameras. It is possible to compute equivalent aperture by multiplying the lens aperture by the crop factor (a.k.a. focal length multiplier). In the vast majority of circumstances, opting for the more modern model (the Panasonic DC G91 / G95) would be a sensible course of action. The magnifications of the viewfinders of both cameras are shown in this infographic.
In particular, vloggers and photographers who are interested in capturing selfies will find this function to be quite useful. The shutter speed information provided pertains to the usage of a mechanical shutter and is not accurate. However, some cameras simply have an electronic shutter, and others have both an electronic and a mechanical shutter in addition to one another. In reality, both of the cameras under discussion are equipped with an electronic shutter, which allows them to shoot absolutely silently when necessary. While this mode is good for capturing still items, it is less ideal for photographing moving objects or shooting under artificial lighting. Although the G95 has a greater resolution than the FZ2000 (20.2MP), the individual pixels on the G95 are bigger (pixel pitch of 3.34mm against 2.41mm on the FZ2000) owing to the larger sensor on the G95 (pixel pitch of 3.34mm compared 2.41mm on the FZ2000).
All of these features, including high resolution, weatherproof bodies, and a large dynamic range, are essential. In this purchasing guide, we’ve compiled a list of the greatest landscape photography cameras available, and we’ve suggested the best of them. To put it another way, these cameras have the same sensor size but have different megapixel counts. Because of its additional 0.3 Megapixels, you can expect the Panasonic G95 to provide better information than the competition. Increased resolution may also make it possible to crop photos more harshly in certain cases.
The Screen and Viewfinder of the Panasonic Gx9 against the Panasonic Lumix DC GX9 vs Panasonic Lumix DMC G95 Panasonic G95
Here is a comparison of the Panasonic GX9 and Panasonic G95, which are both Advanced Mirrorless digital cameras manufactured by Panasonic and available for purchase. GX9 and G95 have equal picture resolution (20.3MP), and both cameras have the same sensor size (APS-C sized sensor). With a resolution of 2.36 megapixels and a magnification of around 0.74x, the DC G91/electronic G95’s viewfinder is a standout feature.
Both the FZ2000 and the G95 are recent models that are now available in the company’s product line-up, respectively. The Panasonic FZ2000 succeeded the previous Panasonic FZ1000, while the Panasonic G95 was a successor to the Panasonic G85. The official Panasonic website has further information on the two cameras (e.g., user guides and manuals), as well as on the connected accessories. The essential physical specifications of the two cameras, as well as a larger range of comparable cameras, are summarized in the table below.
The G95 is capable of supporting UHS-II cards (which can transfer data at speeds of up to 312 MB/s), whilst the FZ2000 is capable of supporting UHS-I cards (which can transfer data at speeds of up to 104 MB/s). The surface area of a sensor is derived by multiplying the sensor’s width and height together. Pixel pitch is a measurement of the distance between the centers of one pixel and the centers of the next. Because the Panasonic G95 has a higher Overall Score than the Panasonic GX9, we believe it is the better option if we had to choose between the two cameras. The LCD panels of the Panasonic G95 and Panasonic GX9 are the same size, measuring 3.00 inches diagonally.
The physical sensor features and sensor quality results are summarized in the table below, and they are compared across a group of cameras that are comparable in design. Larger pixels have the ability to gather more photons, resulting in a broader dynamic range, but smaller pixels enable better resolutions for a given sensor area, resulting in a more compact sensor. Larger sensors are more effective since they have a larger surface area for capturing light than smaller sensors. When comparing digital cameras, the generation of the camera is also a significant thing to consider. These powerful cameras should be sturdy and well-built, have rapid autofocus and shutter speeds for recording fast-moving action, and produce images of professional-level clarity.
Generally speaking, larger pixels provide a higher signal to noise ratio and a wider dynamic range. Also bear in mind that when comparing two interchangeable camera bodies, the weight of the bodies is not the only thing to consider; you must also consider the weight of the lenses that will be used with the cameras. Because the Micro Four Thirds lens mount and Four Thirds sized sensors on both the Panasonic G95 and Panasonic GX9 are the identical, lenses will not be a difference in terms of overall system size. Below is a side-by-side comparison of the technical specifications of the two cameras, which should help you quickly assess their differences and similarities.
Both the Panasonic FZ2000 and the Panasonic G95 are equipped with an intervalometer. In this way, the photographer may film time lapse sequences of natural phenomena such as flower blossoming and sunsets and moon rises without the need to invest in an additional camera trigger and associated software. The following side-by-side comparison compares the physical dimensions and weight of the Panasonic FZ2000 and the Panasonic G95 digital still cameras. There are three sequential viewpoints available: from the front, from the top, and from the rear.
Because aperture is a feature of the lens, it can only be determined for fixed lens cameras. The equivalent aperture for the Panasonic Lumix DC-GX9 is calculated by multiplying the aperture of the lens you are currently using by the crop factor. The equivalent aperture for the Panasonic Lumix DC-G95 is calculated by multiplying the aperture of the lens you are currently using by the crop factor. The greater the pixel pitch, the greater the distance between them and the greater the size of each pixel.