Panasonic Lumix DMC-G3

Panasonic Lumix DMC-G3
Overview
Panasonic DMC-G3, with 14-42mm lens
Type	Micro Four Thirds System
Lens
Lens	Micro Four Thirds System mount
Sensor/Medium
Sensor	17.3 × 13.0 mm Live MOS
Maximum resolution	4592 x 3448 (16.7 megapixels, 16.0 mp effective) 4:3 native; 3:2, 16:9, 1:1 image format(cropped from 4:3 native image format)
ASA/ISO range	ISO 160–6400
Storage	SD, SDHC
Focusing
Focus modes	Automatic or Manual
Exposure/Metering
Exposure modes	Manual, Program, Automatic, Shutter Priority, Aperture Priority
Exposure metering	Intelligent Multiple (Center weighted, average and spot)
Flash
Flash	Built-in pop up, GN 10.5m (ISO 160)
Flash bracketing	±2.0 EV in ⅓ EV steps 3,5,7 frames* • 1/3 or 2/3 , +/−2.0 EV steps
Shutter
Shutter	focal-plane
Shutter speed range	60–1/4000 sec
Viewfinder
Viewfinder	EVF color display, 100% field of view, 0.7x (35mm equiv), 1.4x magnification, with 1.44M dots equivalent; LCD or articulated multi-angle 3-inch (76 mm) inch color LCD (460,000 dots equivalent)
Image Processing
Custom WB	custom modes
General
Battery	Li-Ion 7.2 V, 1010 mAh
Weight	body 336 g; with 14–42 mm lens, battery and card 558 g

The Panasonic Lumix DMC-G3 is a digital mirrorless interchangeable lens camera adhering to the joint Olympus and Panasonic Micro Four Thirds System (MFT) system design standard.^[1] The Panasonic Lumix DMC-G3 is the eighth Panasonic MFT camera introduced under the standard and the thirteenth model MFT camera introduced by either Olympus or Panasonic, as of the G3 product announcement date.

The G3 includes full HD video recording capability in AVCHD format in accordance with the MFT system design standard. The G3 is not the successor to the Panasonic Lumix DMC-G2 but is sold alongside it, placing the G2 in the entry-level position that the now-discontinued G10 once occupied. The G series cameras are designed primarily for users interested in still photography, with the more expensive GH series geared towards users who are interested in greater video functionality. Significantly, the G3 design departs from previous G-series designs with a smaller size, new sensor design and increased processing power.

Physically, the G3 approximates the size of the small Panasonic Lumix DMC-GF2, but includes an electronic viewfinder (EVF) and an articulated, touch control-enabled LCD panel. This made the G3, upon its introduction, the smallest available MFT camera with a built-in EVF, 25% smaller than the G2. The G3's smaller physical size limits the space available for manual control buttons and dials, with many functions now controllable through the articulated 3-inch (76 mm) LCD touch panel on the camera back.

The G3 has a 16.7 megapixel sensor derived from the one in the top-of-the-line Panasonic Lumix DMC-GH2.^[2] This is an improvement over the previous 12.1 megapixel four thirds sensors used by other Olympus and Panasonic MFT cameras, with the exception of the unique multi-aspect sensors used on the Panasonic Lumix DMC-GH1 and GH2 hybrid video/still MFT cameras.

The G3 has faster Auto focus speed than most previous Panasonic MFT cameras. Panasonic claims that it possesses a revised JPEG engine which reputedly renders more pleasing colours (e.g., skin tones), with higher image quality and lower noise at higher ISO than any of the previous Panasonic cameras, with the possible exception of the GH2. However, some reviewers have criticised the quality of the G3s JPEG files.^[3]^[4]

At the center top of the G3 there are weak built-in pop up flash with GN10.5 at ISO160 (GN8.3 at ISO100), hot shoe and stereo microphone (G2 still monoaural).^[5] It is important to note that the G3 includes no external microphone input that the older G2 does.

The G3 was announced in May 2011, and started shipping in June 2011. Available colors, depending on market, were black, chocolate brown, red and white. In the United States, the suggested MSRP for the camera and 14-42mm kit lens was USD 700.00 and GBP628.99 in the United Kingdom^[6]

About the Micro Four Thirds System

The Micro Four Thirds (MFT) system design standard was jointly announced in 2008^[7] by Olympus and Panasonic, as a further evolution of the similarly named predecessor Four Thirds System^[8] pioneered by Olympus. The Micro Four Thirds system standard uses the same sized sensor as the original Four Thirds system, which is half the size of a 35mm camera sensor. One advantage of the smaller sensor is smaller and lighter lenses, but one disadvantage is lower image quality. For example, a typical Olympus MFT M.Zuiko 14-42mm f/3.5-5.6 kit lens weighs 112g, is 56mm in diameter and 50mm in length.^[9] The equivalent Canon APS-C DSLR EF-S 18-55mm f3.5-5.6 kit lens weighs 190g, and is 69mm in diameter and 80mm in length^[10] In 35mm camera format the Micro Four Thirds system sensor has a 2x magnification factor on its lenses whereas the APS-C sized sensor cameras have 1.6x magnification factor.

While the older Four Thirds system design standard allowed the incorporation of a single lens reflex (SLR) camera design including a mirror box and pentaprism based optical viewfinder system, the MFT system design standard sought to pursue a technically different camera, and specifically slimmed down the key physical specifications which eliminated the ability to include the traditional complex optical path and the bulky mirror box needed for a SLR optical viewfinder. Instead, MFT uses either a built-in (Panasonic) or optional (Olympus/Panasonic) compact electronic viewfinder (EVF) and/or LCD back panel displaying a Live view from the main image sensor. Use of an EVF/back panel LCD and smaller four thirds image sensor format and allows for smaller and lighter camera bodies and lenses. The MFT system offers better video recording functionality than traditional DSLRs.

MFT cameras are physically slimmer than most interchangeable lens cameras because the standard specifies a much reduced lens mount flange to imaging sensor plane distance of 20mm. Typically this so-called flange focal distance is over 40mm on most interchangeable lens cameras. The MFT system design flange focal length distance allows for, through use of an adapter, the possibility to mount virtually any manufacturer's existing and legacy still camera interchangeable lens (as well as some video and cine lenses) to an MFT body, albeit using manual focus and manual aperture control. For example, many theoretically obsolete 35mm film camera lenses, as well as existing current lenses for APS-C and full frame DSLR's are now usable on MFT cameras.

Firmware Updates

Panasonic Releases

Panasonic has announced the following firmware update^[11]

Version	Release Date	Notes
1.1	October 2011	Compatibility update for new Panasonic X class lenses with power zoom feature. 1. Display of the local length When you zoom, the focal distance is displayed and you can confirm the zoom position. 2. Step zoom When you operate the zoom, the zoom will stop at positions corresponding to predetermined distances. 3. Zoom resume When you switch the power switch [ON], the zoom positions when you last switched [OFF] are automatically restored. 4. Selectable zoom speed Users can select the speed of electric-powered zooming.
1.2	2011-10-12	Enhances the operation of Micro Four Thirds Lens, when coupled via a v1.1 mount adapter. The update adds a POWER ZOOM LENS option to the CUSTOM menu, with the following sub-options:- DISP FOCAL LENGTH (On/Off), STEP ZOOM (On/Off), ZOOM RESUME (On/Off), ZOOM SPEED (H/M/L), ZOOM RING (On/Off))

Recording Formats

Still Photography Formats

Recording File Format	Image Quality	Aspect Ratio	Image Size
JPEG (DCF, Exif 2.3) RAW DPOF compatible MPO (When attaching 3D lens in Micro Four Thirds System standard)	RAW RAW+Fine RAW+Standard Fine Standard MPO+Fine MPO+Standard (When attaching 3D lens in Micro Four Thirds System standard)	4:3	4,592 x 3,448 (L) [16M] 3,232 x 2,424 (M) [8M] 2,272 x 1,704 (S) [4M] 1,824 x 1,368 (When attaching 3D lens in Micro Four Thirds System standard)
		3:2	4,576 x 3,056 (L) [14M] 3,232 x 2,160 (M) [7M] 2,272 x 1,520 (S) [3.5M] 1,824 x 1,216 (When attaching 3D lens in Micro Four Thirds System standard)
		16:9	4,576 x 2,576 (L) [11.5M] 3,232 x 1,824(M) [6M] 1,920 x 1,080 (S) [2M] 1,824 x 1,024 (When attaching 3D lens in Micro Four Thirds System standard)
		1:1	3,424 x 3,424 (L) [11.5M] 2,416 x 2,416 (M) [6M] 1,712 x 1,712 (S) [3M] 1,712 x 1,712 (When attaching 3D lens in Micro Four Thirds System standard)

AVCHD Format (.MTS files)

Menu Designation	Aspect Ratio	Resolution	Frame Rate	Bit Rate
NTSC Full HD	16:9	1080i 1920 × 1080	60i (sensor output is 30p)	FSH: 17 Mbit/s
NTSC HD	16:9	720p 1280 x 720	60p (sensor output is 30p) (60p done with frame dup)	H: 13, L: 9 Mbit/s
PAL Full HD	16:9	1080i 1920 × 1080	50i (sensor output is 25p)	FSH: 17 Mbit/s
PALS HD	16:9	720p 1280 x 720	50p (sensor output is 25p) (50p done with frame dup)	H: 13, L: 9 Mbit/s

M-JPEG Format (.MOV files)

Menu Designation	Aspect Ratio	Resolution	Frame Rate	Bit Rate
HD	16:9	1280 × 720	30 frame/s	~8 MB/s
WVGA	16:9	848 × 480	30 frame/s	~3.5 MB/s
VGA	4:3	640 × 480	30 frame/s	~2.7 MB/s
QVGA	4:3	320 × 240	30 frame/s	~0.7 MB/s

Micro Four Thirds Camera introduction roadmap

See: Micro Four Thirds System Cameras

References

↑ "Micro Four Thirds | Benefits of Micro". Four Thirds. Retrieved 2012-02-10.
↑ "Rozmowa z Michiharu Uematsu z firmy Panasonic". Fotopolis.pl. Retrieved 2012-02-10.
↑ "Panasonic DMC G3 Review: 19. Conclusion: Digital Photography Review". Dpreview.com. Retrieved 2012-02-10.
↑ "Panasonic Lumix DMC-G3 RAW vs JPEG". Cameralabs. Retrieved 2012-02-10.
↑ "DCRP Panasonic Lumix DMC-G3 Review". Retrieved October 25, 2011.
↑ "Panasonic Lumix DMC-G3 Compact System Camera - Review". Imaging-resource.com. Retrieved 2012-02-10.
↑ "Olympus / Panasonic announce Micro Four Thirds: Digital Photography Review". Dpreview.com. Retrieved 2012-02-10.
↑ "Standard". Four Thirds. Retrieved 2012-02-10.
↑ "Micro Four Thirds | Products(Lenses)". Four Thirds. 2011-08-26. Retrieved 2012-02-10.
↑ "Canon EF-S 18-55mm f/3.5-5.6 II: Digital Photography Review". Dpreview.com. 2005-02-17. Retrieved 2012-02-10.
↑ "The World's First Digital Interchangeable Power Zoom Lenses | Press Release | LUMIX | Digital Camera | Panasonic Global". Panasonic.net. Retrieved 2012-02-10.

External links

Wikimedia Commons has media related to Panasonic Lumix DMC-G3 and Taken with Panasonic Lumix DMC-G3.

Panasonic Lumix DMC-G3 Review - dpreview.com
Panasonic Lumix DMC-G3 Review - cameralabs.com
Panasonic Lumix DMC-G3 Review - imaging-resource.com
Panasonic Lumix DMC-G3 Review - photographyblog.com

Preceded by Panasonic Lumix DMC-G2	Panasonic Micro Four Thirds System cameras October 2008–present	Succeeded by -

Panasonic Lumix cameras

3D series	3D1

F series	FX37 FX77 FX90 FX150 FX700 FZ1 FZ5 FZ7 FZ8 FZ18 FZ20 FZ28 FZ30 FZ38 FZ45 FZ48 FZ50 FZ62 FZ72 FZ100 FZ150 FZ200 FZ300 FZ1000

G series	G1 G2 G3 G5 G6 G7 G10 GF1 GF2 GF3 GF5 GF6 GF7 GH1 GH2 GH3 GH4 GM1 GM5 GX1 GX7 GX8

L series	L1 L10 LC43 LF1 LS5 LX3 LX5 LX7 LZ2 LZ20 LZ30 LX100

S series	SZ1 SZ3 SZ7 SZ9

T series	TZ3 TZ10 TZ18 TZ20 TZ25 TZ30 TZ35 TZ40 TZ60 TZ70 TZ80 TZ90 TZ100

X series	XS1

FS-Series	FS3 FS5

Category:Panasonic Lumix cameras

DSLR, SLT and MILC cameras with HD video (uncompressed – 4K resolution) mode (comparison)

Canon
EOS

High-end	5D Mark II^w (2008) 7D^gw (2009) 1D Mark IV^w (2009) 1D X^gw (2012) 5D Mark III^Hgw (2012) 1D C^gw (2012) 6D^HGW (2012) 7D Mark II^THGw (2014) 5Ds/5DsR^THw (2015) 1D X Mark II^THGw (2016) 5D Mark IV^THGW (2016)

Mid-range	500D (2009) 60D^w (2010) 550D^w (2010) 600D^w (2011) 650D^gHw (2012) EOS M^Hwg (2012) 700D^gHw (2013) 70D^gHW (2013) EOS M2 (2013) 750D^gHW (2015) 760D^gHW (2015) EOS M3^HW (2015) 80D^gTHW (2016) EOS M5^THW (2016)

Entry-level	1100D^w (2011) 100D^H (2013) 1200D^gw (2014) EOS M10^HW (2015) 1300D^gW (2016)

Nikon
D / 1 series

High-end	D300S^Tgw (2009) D3S^Tgw (2009) D800/D800E^THgw (2012) D4^THgw (2012) D600^THgw (2012) D610^THgw (2013) D4S^THgw (2014) D810^THgw (2014) D750^THgW (2014) D810A^THgw (2015) D500^THgW (2016) D5^THgw (2016)

Mid-range	D90^gw (2008) D5000^Tgw (2009) D7000^Tgw (2010) D5100^THgw (2011) 1 V1^TSFgw (2011) 1 V2^SFgw (2012) D5200^THgw (2012) D7100^THgw (2013) D5300^THGW (2013) 1 V3^SFHPgW (2014) D5500^THgW (2015) D7200^THgW (2015) D5600^THgW (2016)

Entry-level	D3100^gw (2010) 1 J1^SFw (2011) D3200^gw (2012) 1 J2^SFHPw (2012) 1 S1^SFHPw (2013) 1 J3^SFHPw (2013) 1 AW1^SFHPGw (2013) D3300^Pgw (2014) 1 J4^SFHPW (2014) 1 J5^TSFHPW (2015) D3400^gw (2016)

Olympus
Micro 4/3

Mid-range	E-M5 (2012) E-P5^W (2013) E-M1^HW (2013) E-M10^THW (2014) PEN-F^THW (2016) E-M1 Mark II^THW (2016)

Entry-level	E-PL1 (2010) E-P1 (2010) E-P2 (2010) E-PL2 (2011) E-PL3 (2011) E-P3 (2011) E-PM1 (2011) E-PL5^W (2012) E-PM2 (2012) E-PL7^W (2014) E-PL8^W (2016)

Panasonic
Lumix

Mid-range	GH1 (2009) GH2 (2010) GH3^THW (2012) GX7 (2013) GM1^THW (2013) GH4^THW (2014)

Entry-level	GF1 (2009) G10 (2010) G2 (2010) GF2 (2010) G3 (2011) GX1 (2011) GF3 (2011) GF5 (2012) G5 (2012) G6 (2013)

Pentax
645 / K /
Q series

High-end	645Z^THgw (2014) K-1^THGW (2016)

Mid-range	K-7^TH (2009) K-5^THg (2010) K-30^THg (2012) K-5 II/K-5 IIs^THg (2012) K-50^THg (2013) K-3^THgw (2013) K-3 II^THGw (2015) K-70^THgw (2016)

Entry-level	K-x^H (2009) K-r^THg (2010) Q^T (2011) K-01^THg (2012) Q10^T (2012) K-500^THg (2013) Q7^T (2013) Q-S1^T (2014)

Samsung
NX series

High-end	NX1 (2014)

Mid-range	NX5^Pg (2010) NX10^Pg (2010) NX11^Pg (2010) NX20^PgW (2012) NX30 (2013) Galaxy NX^PgW (2013) NX500 (2015)

Entry-level	NX100^Pg (2010) NX200^Pg (2011) NX1000^PgW (2012) NX210^PgW (2012) NX300^PgW (2013) NX1100^PgW (2013) NX2000^PgW (2013)

Sony
α

High-end	α99V^HPG/α99^HP (2012) α7/α7R^HPgW (2013) α7S^SHPgW (2014) α7II^HPgW (2014) α7RII^SHPgW (2015) α7SII^SHPgW (2015) α99 II (2016)

Mid-range	α580^HP (2010) α560^HP (2010) α55V^HPG/α55^HP (2010) α77V^HPG/α77^HP (2011) NEX-7^HP (2011) NEX-6^HPW (2011) α65V^HPG/α65^HP (2011) α57^HP (2012) α58^HP (2013) α6000^HPW (2014) α77 II^HPW (2014) α6300^SHPgW (2016)

Entry-level	NEX-3/NEX-3C^HP (2010) NEX-5/NEX-5C^HP (2010) α33^HP (2010) α35^HP (2011) NEX-5N^HP (2011) NEX-C3^HP (2011) NEX-F3^HP (2012) α37^HP (2012) NEX-5R^HPW (2012) NEX-5T^HPW (2013) α3000 (2013) α5000 (2014)

Leica M
Fujifilm X

High-end	Leica M (2012) Leica S (2014) Fujifilm X-Pro2^W (2016) Fujifilm X-T2^PTW (2016)

Mid-range	Fujifilm X-Pro1 (2012) Fujifilm X-E1 (2012) Fujifilm X-E2^W (2013) Fujifilm X-T1^W (2014) Fujifilm X-T10^W (2015)

Entry-level	Fujifilm X-M1^W (2013) Fujifilm X-A1^W (2013) Fujifilm X-A2^W (2015) Fujifilm X-A3^PW (2016) Fujifilm X-A10^W (2016)

Hasselblad XCD

High-end	Hasselblad X1D-50c^GW (2016)

Timelapse^T — Slow motion^S — Fast fps^F — HDR^H — Panorama^P — GPS^G(opt.)^g — WiFi^W(opt.)^w

Micro Four Thirds cameras timeline

System	Form	Class	2008		2009				2010				2011				2012				2013				2014				2015				2016				2017
			3	4	1	2	3	4	1	2	3	4	1	2	3	4	1	2	3	4	1	2	3	4	1	2	3	4	1	2	3	4	1	2	3	4	1	2	3	4

Olympus	SLR style OMD	High-end																						E-M1												E-M1 II
		Advanced																E-M5											E-M5 II
		Mid-range																							E-M10						E-M10 II
	Rangefinder style PEN	Mid-range				E-P1		E-P2						E-P3								E-P5												PEN-F
		Upper-entry							E-PL1				E-PL2		E-PL3					E-PL5		E-PL6					E-PL7									E-PL8
		Entry-level												E-PM1						E-PM2
	remote																																		Air

Panasonic	SLR style	High-end			GH1						GH2								GH3						GH4													(GH5)
		Mid-range	G1						G2					G3					G5			G6									G7					G85/G80
		Entry-level							G10
	Rangefinder style	Advanced														GX1							GX7								GX8
		Mid-range																																GX80
		Upper-entry																						GM1				GM5
		Entry-level					GF1					GF2		GF3				GF5				GF6							GF7					GF8
	Camcorder	Professional															AG-AF104

Kodak	Rangefinder style	Entry-level																								S-1

YI	Rangefinder style	Entry-level																																		M1

Z Camera		Entry-level																														E1

JVC	Camcorder	Professional																											GY-LS300

SVS-Vitek	-	Industrial																	EVO Tracer

Video is not available on this device
Weather sealed
in-body stabilization (5-axis)
Touchscreen (italic)

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