U.S. patent application number 17/729736 was filed with the patent office on 2022-08-11 for video signal conversion device.
The applicant listed for this patent is AVerMedia Technologies, Inc.. Invention is credited to Ssu-Ming Cheng, Shi-Jie Lin, Hong-Wei Liu, Chih-Sheng Wang, Chen-Hsiang Wu, Yen-Cheng Yao.
Application Number | 20220256113 17/729736 |
Document ID | / |
Family ID | |
Filed Date | 2022-08-11 |
United States Patent
Application |
20220256113 |
Kind Code |
A1 |
Cheng; Ssu-Ming ; et
al. |
August 11, 2022 |
VIDEO SIGNAL CONVERSION DEVICE
Abstract
A video signal conversion device includes a frontend interface
circuit, a FPGA video processor and a backend interface circuit.
The frontend interface circuit receives a HDR video input signal
from a video transmitting device. The FPGA video processor outputs
a SDR first video output signal. A video receiving device receives
the first video output signal and a HDR second video output signal
from the FPGA video processor through the video bridge controller
of the backend interface circuit by PCI-E.
Inventors: |
Cheng; Ssu-Ming; (New Taipei
City, TW) ; Liu; Hong-Wei; (New Taipei City, TW)
; Wu; Chen-Hsiang; (New Taipei City, TW) ; Lin;
Shi-Jie; (New Taipei City, TW) ; Yao; Yen-Cheng;
(New Taipei City, TW) ; Wang; Chih-Sheng; (New
Taipei City, TW) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
AVerMedia Technologies, Inc. |
New Taipei City |
|
TW |
|
|
Appl. No.: |
17/729736 |
Filed: |
April 26, 2022 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
17095779 |
Nov 12, 2020 |
11343466 |
|
|
17729736 |
|
|
|
|
16395393 |
Apr 26, 2019 |
10868998 |
|
|
17095779 |
|
|
|
|
International
Class: |
H04N 7/01 20060101
H04N007/01; H04N 5/355 20060101 H04N005/355; H04N 5/235 20060101
H04N005/235 |
Foreign Application Data
Date |
Code |
Application Number |
Apr 30, 2018 |
TW |
107114650 |
Claims
1. A video signal conversion device, which is cooperated with a
video transmitting device, wherein the video signal conversion
device is coupled with the video transmitting device for receiving
a video input signal transmitted from the video transmitting
device, wherein the video input signal is a signal with a first
frame rate, comprising: a video processing module, which output a
first video output signal in accordance with the video input signal
with the first frame rate, wherein the video processing module
converts the first frame rate to a second frame rate being smaller
than the first frame rate, so that the first video output signal is
a signal with the second frame rate; and wherein the video
processing module substantially synchronously output the first
video output signal with the second frame rate and a second video
output signal, wherein the second video output signal is a signal
with the first frame rate, wherein the first frame rate is greater
than the second frame rate.
2. The video signal conversion device of claim 1, wherein the video
processing module outputs the second video output signal with the
first frame rate by pass-through.
3. The video signal conversion device of claim 2, wherein the video
signal conversion device is cooperated with a video receiving
device, wherein the video receiving device substantially
synchronously receives the first video output signal and the second
video output signal outputted by the video processing module of the
video signal conversion device.
4. The video signal conversion device of claim 1, wherein the first
video output signal with the second frame rate is to save bandwidth
by series flow, while the second video output signal with the first
frame rate is stored for the user to use the high frame rate
video.
5. The video signal conversion device of claim 1, wherein the first
frame rate is equal to or more than 60 frames/s (FPS), the second
frame rate is equal to or less than 60 frames/s (FPS).
6. The video signal conversion device of claim 1, wherein the video
processing module generates the second video output signal with the
first frame rate by video operation, where the video operations is
change of resolution rate, frame rate or other video
parameters.
7. The video signal conversion device of claim 1, wherein the first
video output signal with the second frame rate is SDR signal and
the second video output signal with the first frame rate is HDR
signal.
8. The video signal conversion device of claim 1, wherein the video
receiving device transmits relevant command or information to the
video signal conversion device to control the video processing
module for corresponding video processing, where the video
processing module converts the video input signal with the first
frame rate to the first video output signal with the second frame
rate.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application is a continuation application of U.S.
application Ser. No. 17/095,779 filed Nov. 12, 2020, which is a
divisional application of U.S. application Ser. No. 16/395,393
filed Apr. 26, 2019, which claims priority to Taiwan Application
No. 107114650 filed Apr. 30, 2018.
BACKGROUND
1. Technical Field
[0002] The present invention generally relates to a conversion
device, and more particularly, to a video conversion device.
2. Description of Related Art
[0003] At present, the high dynamic range (HDR) video is getting
more and more accepted by the frontend video source device, for
example, the video game console PS4 have output game video
supporting HDR format. At present, however, in the design of the
video product, the backend video manufacturers do not consider
whether backend video recovering end supports the HDR formation,
for example, during video recording, display and other video
application. In this case, for example, when the signal from the
frontend to backend (a video receiving end) is the video signal of
HDR format but the backend (the video receiving end) does not
support the HDR format, the user may easily become aware that the
video format fails to meet the caused color anomaly.
[0004] Therefore, it is obvious that existing video transmitting
device has the problems to be solved.
SUMMARY OF THE INVENTION
[0005] The present invention is to provide a video signal
conversion device, which is cooperated with a video transmitting
device and a video receiving device. The video signal conversion
device includes a frontend circuit, a FPGA video processor and a
backend circuit. The frontend circuit is electrically connected
with the video transmitting device to receive the video input
signal from the video transmitting device, where the video input
signal is HDR signal. The FPGA video processor is electrically
connected with the frontend circuit. According to the video input
signal, the FPGA video processor outputs a first video output
signal, and the first video output signal is SDR signal. The
backend circuit is electrically connected with the FPGA video
processor and the video receiving device respectively, wherein, the
backend circuit includes a video bridge controller, the video
bridge controller is PCI-E BUS, and the video receiving device
meets PCI-E BUS format by the video bridge controller to receive
the first video output signal from the FPGA video processor.
[0006] Therefore, according to the technical content of the
invention, the video signal conversion device can more fully solve
the problems that the backend video receiving end does not support
HDR or the backend video receiving end requires SDR.
[0007] The detailed technology and preferred embodiments
implemented for the subject invention are described in the
following paragraphs accompanying the appended drawings for people
skilled in this field to well appreciate the features of the
claimed invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0008] The parts in the drawings are not necessarily drawn to
scale, the emphasis instead being placed upon clearly illustrating
the principles of at least one embodiment. In the drawings, like
reference numerals designate corresponding parts throughout the
various diagrams, and all the diagrams are schematic.
[0009] FIG. 1 is a schematic diagram showing a video signal
conversion device according to a first embodiment of the
invention.
[0010] FIG. 2 is a schematic diagram showing a frontend interface
of the video signal conversion device according to the first
embodiment of the invention.
[0011] FIG. 3 is a schematic diagram showing a video signal
conversion device according to a second embodiment of the
invention.
[0012] FIG. 4 is a schematic diagram showing a video signal
conversion device according to a third embodiment of the
invention.
[0013] FIG. 5 is a schematic diagram showing a video signal
conversion device according to a fourth embodiment of the
invention.
[0014] FIG. 6 is a schematic diagram showing a video signal
conversion device according to a fifth embodiment of the
invention.
DETAILED DESCRIPTION
[0015] Reference will now be made to the drawings to describe
various inventive embodiments of the present disclosure in detail,
wherein like numerals refer to like elements throughout.
[0016] The terminology used herein is for the purpose of describing
the particular embodiment and is not intended to limit the
application. The singular forms "a", "an", "the", "this" and
"these" may also include the plural.
[0017] As used herein, "the first", "the second", etc., are not
specifically meant to refer to the order, nor are they intended to
limit the application, but are merely used to distinguish elements
or operations that are described in the same technical terms.
[0018] As used herein, "coupled" or "connected" may mean that two
or more elements or devices are directly contacted in physical with
each other, or indirectly contacted in physical with each other,
may also mean that two or more elements or devices operate or
interact with each other, and may also refer to a direct or
indirect connection by electrical (or electrical signals).
[0019] As used herein, "including", "comprising", "having", and the
like are all open type terms, meaning to include but not limited
to.
[0020] As used herein, "and/or" includes any one or all
combinations of the recited.
[0021] Regarding the directional terminology used herein, for
example, up, down, left, right, front or back, etc., only refers to
the direction of the additional drawing. Therefore, the directional
terminology used is used to illustrate that it is not intended to
limit the application.
[0022] The terms used in this specification, unless otherwise
noted, usually have the usual meaning of each term used in this
field, in the context of the application, and in particular
content. Certain terms used to describe the present invention are
discussed below or elsewhere in this specification to provide
additional guidance to those skilled in the art in the description
of the present invention.
[0023] As used herein, "video input signal" and "video output
signal" mentioned in this specification refer to signals containing
at least video information, and of course, audio and video signals,
and there is no limit here.
[0024] A video signal conversion device disclosed in the embodiment
may be cooperated with a video transmitting device and a video
receiving device. The video signal conversion device includes a
frontend interface, a video processing module and a backend
interface. The frontend interface is coupled with the video
transmitting device to receive the video input signal from the
video transmitting device, where the video input signal is high
dynamic range signal. The "high dynamic range" is hereinafter
referred to as HDR. The video processing module is coupled with the
frontend interface. According to the video input signal, the video
processing module outputs the first video output signal, wherein
the first video output signal is standard display range signal. The
"standard display range" is hereinafter referred to as SDR. The
backend interface is coupled with the video processing module and
the video receiving device respectively, wherein the video
receiving device receives the first video output signal from the
video processing module by the backend interface.
[0025] The video transmitting device may send the HDR video input
signal at least, for example, it may only send HDR video input
signal, or may send HDR and/or SDR, or other video input signal.
The frontend interface may have different designs subject to actual
requirement, for example, the video processing module may be
operated by the frontend interface and receives the video
information of the video input signal from the video transmitting
device for subsequent processing. For example, the frontend
interface may be the frontend circuit. Additionally, the frontend
interface may, for example, include a video receiving device, or a
video shunt, which support HDMI or other format videos
respectively. According to the conversion signal, the video
processing module may, for example, convert the video information
of the video input signal into SDR video information to generate
SDR first video output signal. The conversion information may be
known by comparison tables or real-time operations. For the above
conversion, actually, for example, it may be SDR video information
obtained by adjusting the video information video conversion
formula of the conversion information, and this is only used as
example and does not limit this invention. The video processing
module may be implemented by software or hardware circuit, for
example, a processor, a main control unit (MCU), a system on a chip
(SoC), a field programmable gate array (FPGA), etc. The video
receiving device may be the device performing video functions, such
as display/save/stream/live or video edit/export, and the device
realized in a computer or single video function. The video
receiving device may be the device supporting or not supporting
HDR. The backend circuit may include a video bridge controller, and
the video bridge controller may be designed to PCI-E BUS or USB.
The video receiving device enables the video processing module by
the video bridge controller to convert the HDR video input signal
to the SDR first video output signal, for example, the video
receiving device transmits relevant command or information to the
video bridge controller to control the video processing module for
corresponding video processing by the video bridge controller.
[0026] Additionally, the video receiving device may receive the
first video output signal and/or the second video output signal
from the video processing module by the backend interface, wherein
the second video output signal is HDR signal. During actual
operation, according to the HDR video input signal, the video
processing module outputs the HDR second video output signal by
pass-through. Of course, according to the HDR video input signal,
the video processing module may generate the HDR second video
output signal by video operation. These video operations may be,
for example, change of resolution/frame rate or other video
parameters. Additionally, the video processing module may, for
example, substantially synchronously output the SDR first video
output signal and the HDR second video output signal, or
selectively output the SDR first video output signal or the HDR
second video output signal. The detailed description is given below
by embodiments.
[0027] FIG. 1 shows the schematic diagram of the video signal
conversion device of the first embodiment. As shown in FIG. 1, the
video signal conversion device 11 is used together with the video
transmitting device 12 and the video receiving device 13. The video
signal conversion device 11 includes a frontend interface 111, a
video processing module 112 and a backend interface 113. The
frontend interface 111 is coupled with the video transmitting
device 12 to receive the video input signal from the video
transmitting device 12, wherein the video input signal is HDR
signal. The video processing module 112 is coupled with frontend
interface 111. According to the video input signal, the video
processing module 112 outputs the first video output signal V11,
wherein, the first video output signal V11 is SDR signal. The
backend interface 113 is coupled respectively with the video
processing module 112 and the video receiving device 13, wherein,
the video receiving device 13 receives the first video output
signal V11 and the second video output signal V12 from the video
processing module 112, and the second video output signal V12 is
HDR signal.
[0028] As according to the video input signal, the video processing
module 112 outputs the SDR first video output signal V11 and the
HDR second video output signal V12 for the follow-up use by the
video receiving device 13, the video receiving device may be more
suitable for a plurality of video functions supporting or not
supporting HDR. In this embodiment, for example, the SDR first
video output signal V11 may be displayed on the screen not
supporting HDR, and the HDR second video output signal V12 may be
stored for follow-up use. Of course, or, the HDR second video
output signal V12 may be displayed on the screen supporting HDR,
while the SDR first video output signal V11 may be stored for
display in the screen not supporting HDR.
[0029] According to the video input signal, the video processing
module 112 may output the HDR second video output signal V12.
During actual operation, according to the HDR video input signal,
the video processing module 112 may output the HDR second video
output signal V12 by pass-though. Of course, according to the HDR
video input signal, the video processing module 112 may generate
the HDR second video output signal V12 by video operation. This
video operation may be, for example, change of resolution rate,
frame rate or other video parameters. Additionally, the video
processing module 112 may, for example, substantially synchronously
output the SDR video output signal V11 and the HDR second video
output signal V12. The "substantially synchronously" means smaller
time difference within allowable range is deemed as "substantially
synchronously". In another embodiment, the video processing module
112 may respectively output the SDR first video output signal V11
and the HDR second video output signal V12. The backend
interface113 may respectively or substantially synchronously output
the SDR first video output signal V11 and the HDR second video
output signal V12 to the video receiving device 13.
[0030] According to actual requirement, the frontend interface
includes a receiving device and a shunt, for example, as shown in
FIG. 2, the frontend interface 111 includes a HDMI receiving device
1111 receiving the HDMI video input signal from the video
transmitting device 12. The video signal conversion device 11 may
be cooperated with another video receiving device 14, wherein, the
frontend interface 111 further includes a HDMI shunt 1112, wherein
the HDMI shunt 1112 is respectively coupled with the HDMI receiving
device 1111, the video transmitting device 12 and the another video
receiving device 14 and shunts the video input signal to the HDMI
receiving device 1111 and another video receiving device 14. During
actual operation, the HDMI shunt 1112 may output the signal by
pass-through, or change of the resolution/frame rate or other video
parameters, without limitation.
[0031] The video receiving device 13 may enable the video
processing module 112 by the backend interface 113 to convert the
HDR video input signal to the SDR first video output signal V11,
for example, the video receiving device 13 transmits relevant
command or information to the backend interface 113 to control the
video processing module 112 for corresponding video processing by
the backend interface 113. Additionally, the video receiving device
13 may also enable the video processing module 112 to substantially
synchronously or respectively the SDR first video output signal V11
and the HDR second video output signal V12 by the backend interface
113.
[0032] FIG. 3 shows the schematic diagram of the video signal
conversion device according to the second embodiment. As shown in
FIG. 3, the video signal conversion device 31 is cooperated with
the video transmitting device 32 and the video receiving device 33.
The video signal conversion device 31 includes a frontend interface
311, a FPGA video processor 312 and a backend circuit 313. The
frontend interface 311 is electrically connected with video
transmitting device 32 to receive the video input signal from the
video transmitting device 32, wherein the video input signal is HDR
signal. The FPGA video processor 312 is electrically connected with
the frontend circuit 311. According to the video input signal, the
FPGA video processor 312 outputs the first video output signal V31,
wherein, the first video output signal V31 is SDR signal. The
backend circuit 313 is electrically connected with the FPGA video
processor 312 and the video receiving device 33, wherein, the
backend circuit 313 includes a video bridge controller, and the
video bridge controller is PCI-E BUS. The video receiving device 33
receives the PCI-E BUS first video output signal V31 from the FPGA
video processor 312 by the video bridge controller. In other
embodiments, the FPGA video processor 312 also may be a SoC video
processor.
[0033] As mentioned above, according to the HDR video input signal,
the FPGA video processor 312 outputs the SDR first video output
signal V31 for follow-up use by the video receiving device 33, such
as storage, display, or series flow, etc., to more fully apply for
supporting HDR.
[0034] The FPGA video processor 312 may selectively output the
first video output signal V31 or the second video output signal
V32, wherein the second video output signal V32 is HDR signal. In
addition, according to the video input signal, the FPGA video
processor 312 outputs the HDR second video output signal V32.
During actual operation, according to HDR video input signal, the
FPGA video processor 312 outputs the HDR second video output signal
V32 by pass-through. Of course, according to the HDR video input
signal, the FPGA video processor 312 may generate the HDR second
video output signal V32 by video operation. These video operations
may be, for example, change of resolution/frame rate or other video
parameters. Additionally, the backend circuit 313 may, for example,
selectively output the SDR first video output signal V31 or the HDR
second video output signal V32 to the video receiving device 33. Of
course, a buffer may be arranged on the backend circuit 313. Even
if the FPGA video processor 312 selectively outputs the signal
V31/V32, by temporary storage in the buffer of the backend circuit
313, the SDR first video output signal V31 and the HDR second video
output signal V32 may be respectively or substantially
synchronously outputted to the video receiving device 33.
[0035] In this embodiment, according to actual requirements, the
frontend circuit 311 may have different design, for example,
including a HDMI receiving device and a HDMI shunt. The receiving
device and the shunt have been described in the previous
embodiment, and not are repeated in this embodiment.
[0036] The video receiving device 33 may enable the FPGA video
processor 312 by the video bridge controller of the backend circuit
313 to convert the HDR video input signal to the SDR first video
output signal V31, for example, the video receiving device 33
transmits relevant command or information to the video bridge
controller of the backend circuit 313 to control the FPGA video
processor 312 for video processing by the video bridge controller
of the backend circuit 313. In addition, the video receiving device
33 may enable the FPGA video processor 312 by the video bridge
controller of the backend circuit 313 to selectively output the SDR
first video output signal V31 or the HDR second video output signal
V32.
[0037] FIG. 4 shows the schematic diagram of the video signal
conversion device according to the third embodiment. As shown in
FIG. 4, the video signal conversion device 41 is cooperated with
the video transmitting device 42 and the video receiving device 43.
The video signal conversion device 41 includes a frontend interface
411, a video processing hardware circuit 412 and a backend
interface circuit 413. The frontend circuit is electrically
connected with video transmitting device 42 to receive the video
input signal from the video transmitting device 42, wherein the
video input signal is HDR signal. The video processing hardware
circuit 412 is electrically connected with frontend circuit 411.
According to the video input signal, the video processing hardware
circuit 412 outputs the first video output signal V41, wherein, the
first video output signal V41 is SDR signal. The backend interface
circuit 413 is electrically connected respectively with the video
processing hardware circuit 412 and the video receiving device 43,
wherein, the backend interface circuit 413 includes a USB video
bridge controller. The video receiving device 43 receives the first
video output signal V41 from the video processor 412 by the USB
video bridge controller.
[0038] Continued above, according to HDR video input signal, the
video processing hardware circuit 412 outputs the SDR first video
output signal V31 for follow-up use by the video receiving device
43, such as storage, display, or series flow, etc., to more fully
apply for supporting HDR.
[0039] In the embodiment, the video processing hardware circuit 412
may selectively outputs the first video output signal V41 or the
second video output signal V42, wherein the second video output
signal V42 is HDR signal. In addition, according to the video input
signal, the video processing hardware circuit 412 outputs the HDR
second video output signal V42. During actual operation, according
to HDR video input signal, the video processing hardware circuit
412 outputs the HDR second video output signal V42 by pass-through.
Of course, according to the HDR video input signal, the video
processing hardware circuit 412 may generate the HDR second video
output signal V42 by video operation. These video operations may
be, for example, change of resolution/frame rate or other video
parameters. Additionally, the backend interface circuit 413 may,
for example, selectively output the SDR first video output signal
V41 or the HDR second video output signal V42 to the video
receiving device 43. Of course, the signal may be temporarily
stored in a buffer of the backend interface circuit 413. Even if
the video processing hardware circuit 412 selectively outputs the
signal V41/V42, by temporary storage in the buffer of the backend
interface circuit 413, the SDR first video output signal V41 and
the HDR second video output signal V42 may be respectively or
substantially synchronously outputted to the video receiving device
43.
[0040] According to actual requirements, the frontend circuit
411may have different design, for example, including a HDMI
receiving device and a HDMI shunt. The receiving device and the
shunt have been described in the previous embodiment, and not are
repeated in this embodiment.
[0041] The video receiving device 43 may enable the video
processing hardware circuit 412 by the USB video bridge controller
of the backend interface circuit 413 to convert the HDR video input
signal to the SDR first video output signal V41, for example, the
video receiving device 43 transmits relevant command or information
to the video bridge controller of the backend interface circuit 413
to control the video processing hardware circuit 412 for video
processing by the USB video bridge controller of the backend
interface circuit 413. In addition, the video receiving device 43
may enable the video processing hardware circuit 412 by the video
bridge controller of the backend interface circuit 413 to
selectively output the SDR first video output signal V41 or the HDR
second video output signal V42.
[0042] FIG. 5 shows the schematic diagram of the video signal
conversion device according to the fourth embodiment. As shown in
FIG. 5, the video signal conversion device 51 is cooperated with
the video transmitting device 52 and the video receiving device 53.
The video signal conversion device 51 includes a frontend interface
511, a video processing module 512 and a backend interface 513. The
frontend interface 511 is coupled with the video transmitting
device 52 to receive the video input signal from the video
transmitting device 51, wherein the video input signal is HDR
signal. The video processing module 512 is coupled with the
frontend interface 511. According to the video input signal, the
video processing module 511 outputs the first video output signal
V51, wherein, the first video output signal V51 is SDR signal. The
backend interface 513 is electrically connected respectively with
the video processing module 512 and the video receiving device 53,
wherein, the backend interface 513 includes a video bridge
controller 5131. The video receiving device 53 receives the first
video output signal V51 from the video processing module 512 by the
video bridge controller 5131, wherein the video bridge controller
5131 is coupled with the frontend interface 511 to receive the
video metadata M10 corresponding to the video input signal from the
frontend interface 511 for use by the video receiving device
53.
[0043] Continued above, according to HDR video input signal, the
video processing module 512 outputs the SDR first video output
signal V51 for follow-up use by the video receiving device 53, such
as storage, display, or series flow, etc., to more fully apply for
supporting HDR.
[0044] In this embodiment, the video metadata M10 includes the HDR
information on HDR video input signal.
[0045] The video bridge controller 5131 may be a USB video bridge
controller. The USB video bridge controller 5131 transmits the
video metadata M10 to the video receiving device 53 by a universal
sequence. In this embodiment, a USB video extension unit
(UVC-Extension Unit) or a USB human-interface unit (USB-HID)
transmits the video metadata M10 to the video receiving device 53.
Additionally, according to actual requirement, with USB framework,
a channel is designed on the video receiving device 53 to transmit
the video metadata M10 from the backend interface 513 to the video
receiving device 53, without limitation to UVC-Extension Unit or
USB-HID.
[0046] According to conversion signal, the video processing module
512 may convert the HDR video input signal to the SDR first video
output signal. The conversion information is related with the HDR
information of the video metadata. During actual operation, the
conversion information may be obtained by the HDR information and
the HDR-SDR conversion function. The conversion information may be
known by comparison tables or real-time operations. For the above
conversion, actually, for example, it may be SDR video information
obtained by adjusting the video information video conversion
formula of the conversion information.
[0047] In this embodiment, the video processing module 512 may
selectively outputs the first video output signal V51 or the second
video output signal V52, wherein the second video output signal V52
is HDR signal. Additionally, according to the video input signal,
the video processing module 512 outputs the second video output
signal V52. During actual operation, according to the HDR video
input signal, the video processing module 512 outputs the HDR
second video output signal V52 by pass-through. Of course,
according to the HDR video input signal, the video processing
module 512 may generate the HDR second video output signal V52 by
video operation. These video operations may be, for example, change
of resolution/frame rate or other video parameters. The backend
interface 513 may selectively output the SDR first video output
signal V51 or the HDR second video output signal V52 to the video
receiving device 53. Of course, a buffer is arranged on the backend
interface 513. Even if the video processing module 512 selectively
outputs the signal V51/V52, by temporary storage in the buffer of
the backend interface 513, the SDR first video output signal V51
and the HDR second video output signal V52 may be respectively or
substantially synchronously outputted to the video receiving device
53.
[0048] The video receiving device 53 may enable the video
processing module 512 by the video bridge controller 5131 of the
backend interface 513 to convert the HDR video input signal to the
SDR first video output signal V51, for example, the conversion
information may be stored in the video bridge controller 5131. When
the video receiving device 53 transmits relevant command or
information to the USB video bridge controller 5131 of the backend
interface 513, the USB video bridge controller 5131 transmits the
conversion information to the video processing module 512 so as to
control the video processing module 512 for corresponding video
processing. Additionally, the video receiving device 53 may enable
the video processing module 512 by the USB video bridge controller
of the backend interface 513 to selectively output the SDR first
video output signal V51 or the HDR second video output signal
V52.
[0049] In the embodiment, the frontend interface 511 may have
different design according to actual requirement, for example,
including a HDMI receiving device and a HDMI shunt. The receiving
device and the shunt have been described in the previous
embodiment, and not are repeated in this embodiment. Additionally,
the video bridge controller 5131 may be coupled with the receiving
device of the frontend interface 511 to receive the video metadata
M10 corresponding to the video input signal from the receiving
device of the frontend interface 511.
[0050] FIG. 6 shows the schematic diagram of the video signal
conversion device according to the fifth embodiment. As shown in
FIG. 6, the video signal conversion device 21 is cooperated with
the video transmitting device 22 and the video receiving device 23.
The video signal conversion device 21 includes a frontend interface
211, a video processing module 212 and a backend interface 213. The
frontend interface 211 is coupled with the video transmitting
device 22 to receive the video input signal from the video
transmitting device 22, wherein the video input signal is a signal
with a first frame rate. The video processing module 212 is coupled
with the frontend interface 211. According to the video input
signal, the video processing module 212 outputs the first video
output signal V21, wherein, the first video output signal V21 is a
signal with a second frame rate. The backend interface 213 is
respectively coupled with the video processing module 212 and the
video receiving device 23, wherein, the video receiving device 23
receives the first video output signal V21 and the second video
output signal V22 from the video processing module 212 by the
backend interface 213, wherein the second video output signal V22
is a signal with the first frame rate.
[0051] As according to the video input signal, the video processing
module 212 may output the first video output signal V21 with the
second frame rate and the second video output signal V22 with the
first frame rate for follow-up use by the video receiving device
23, the video receiving device is more suitable for the video
functions operating simultaneously. In this embodiment, for
example, the first video output signal V21 with the second frame
rate (e.g. low frame rate) may be used to save bandwidth by series
flow, while the second video output signal V22 with the first frame
rate (e.g. high frame rate) may be stored for the user to use the
high frame rate video.
[0052] The first frame rate may be higher than the second frame
rate, which is not deemed limited. In this embodiment, the first
frame rate is equal to or higher than 60 frames/s (FPS) while the
second frame rate equal to or lower than 60 frames/s (FPS).
[0053] According to the video input signal, the video processing
module 212 outputs the second video output signal V22 with the
first frame rate. During actual operation, according to the video
input signal with the first frame rate, the video processing module
212 outputs the second video output signal V22 with the first frame
rate by pass-through. Of course, according to the video input
signal with the first frame rate, the video processing module 212
may generate the second video output signal V22 with the first
frame rate by video operation. These video operations may be, for
example, change of resolution/frame rate or other video parameters.
Additionally, the video processing module 212 may, for example,
substantially synchronously output the first video output signal
V21 with the second frame rate and the second video output signal
V22 with the first frame rate. The "substantially synchronously"
means smaller time difference within allowable range is deemed as
"substantially synchronously". In another embodiment, the video
processing module 212 may respectively output the first video
output signal V21 with the second frame rate and the second video
output signal V22 with the first frame rate. The backend interface
213 may respectively or substantially synchronously output the
first video output signal V21 with the second frame rate and the
second video output signal V22 with the first frame rate to the
video receiving device 23.
[0054] The video receiving device 23 may enable the video
processing module 212 by the backend interface 213 to convert the
video input signal with the first frame rate to the first video
output signal V21 with the second frame rate, for example, the
video receiving device 23 transmits relevant command or information
to the backend interface 113 to control the video processing module
212 for corresponding video processing by the backend interface
213. Additionally, the video receiving device 23 enables the video
processing module 212 to substantially synchronously or
respectively output the first video output signal V21 with the
second frame rate and the second video output signal V22 with the
first frame rate by the backend interface 213.
[0055] In summary, according to the technical content of the
invention, the video signal conversion device can more fully solve
the problems that the backend video receiving end does not support
HDR or the backend video receiving end requires SDR.
[0056] Even though numerous characteristics and advantages of
certain inventive embodiments have been set out in the foregoing
description, together with details of the structures and functions
of the embodiments, the disclosure is illustrative only. Changes
may be made in detail, especially in matters of arrangement of
parts, within the principles of the present disclosure to the full
extent indicated by the broad general meaning of the terms in which
the appended claims are expressed.
* * * * *