INNCOM International Inc. 027060TXR Benutzerhandbuch
M O D E V A R e f e r e n c e M a n u a l
P a g e 3 o f 1 6
Service LED
and Switch
IR Rx
CPU
WBI Gang 1
WBI Gang 2
WBI Gang 3
Touch PCB
Interface 3
Touch PCB
Interface 1
Radio
Circuit
IR Tx
Touch PCB
Interface 2
GND
S5bus
12VDC
GS2 Interface 1
GS2 Interface 2
GS2 Interface 3
Speaker / Piezo
Touch Interface 1
Touch Interface 2
Touch Interface 3
Slider
Slider
Slider
L
E
D
A
rr
a
y
L
E
D
A
rr
a
y
L
E
D
A
rr
a
y
GS2 Logic Board
WBI Mounting Bracket and Actuators
Service LED
and Switch
Service LED
and Switch
GND
S5bus
12VDC
GND
S5bus
12VDC
12VDC Power
supply
Touch Interface
Figure 2 MODEVA System Block Diagram
Note the modular concepts that contribute to the flexibility in the MODEVA system. For instance, the triple gang
assembly uses three touch user interfaces with the same layout and mechanical dimensions but configured in four
different ways (refer to Figure 2 above and Figure 3 below). On the back end, the system’s three actuators can be
used as dimmers or as simple load switchers and can be arranged in any configuration that the application
requires. In between lies the logic board containing all logic and communications control required for nearly any
IRAS application.
assembly uses three touch user interfaces with the same layout and mechanical dimensions but configured in four
different ways (refer to Figure 2 above and Figure 3 below). On the back end, the system’s three actuators can be
used as dimmers or as simple load switchers and can be arranged in any configuration that the application
requires. In between lies the logic board containing all logic and communications control required for nearly any
IRAS application.
3 Touch User Interface
The MODEVA touch user interface contains the touch sensors and indicator LEDs for system input and output. The
touch user interface can be fabricated with a specific geometry and sensor layout to accommodate multiple
applications (while also easing assembly and production) by designing only one touch user interface dimension that
is used for single gang, double gang, and triple gang assemblies.
touch user interface can be fabricated with a specific geometry and sensor layout to accommodate multiple
applications (while also easing assembly and production) by designing only one touch user interface dimension that
is used for single gang, double gang, and triple gang assemblies.
MODEVA incorporates a capacitive controller capable of detecting touch on up to 6 sensors or one single slider
per touch user interface. The sensors sense fields through any dielectric material such as glass or plastic up to
10mm thick. Each sensor can be tuned to a unique sensitivity level. INNCOM plans to provide a single touch user
interface layout at the product launch based on a single slider that can be configured in one of the four following
ways:
per touch user interface. The sensors sense fields through any dielectric material such as glass or plastic up to
10mm thick. Each sensor can be tuned to a unique sensitivity level. INNCOM plans to provide a single touch user
interface layout at the product launch based on a single slider that can be configured in one of the four following
ways:
Basic Slider
0–255 levels of control operated by the slide of a finger across the glass in the up or down direction. This
slider array makes use of all 11 LEDs with the exception of the Red LED. This layout is optimal for slide
dimming a dimmable lighting load or as a drape control.
0–255 levels of control operated by the slide of a finger across the glass in the up or down direction. This
slider array makes use of all 11 LEDs with the exception of the Red LED. This layout is optimal for slide
dimming a dimmable lighting load or as a drape control.
Five segmented slider layout
This layout segments the slider into five evenly distributed discrete sensor locations in software using a
unified hardware layout. In Figure 3 below, the five-segment layout makes use of the corresponding Blue
LEDs. In the five segment configuration, the LEDs change from array functionality to indicator
functionality. This layout is optimal where five or fewer functions (such as lighting control, amenities
such as Do Not Disturb and Make Up Room, and general purpose functionality) are required.
This layout segments the slider into five evenly distributed discrete sensor locations in software using a
unified hardware layout. In Figure 3 below, the five-segment layout makes use of the corresponding Blue
LEDs. In the five segment configuration, the LEDs change from array functionality to indicator
functionality. This layout is optimal where five or fewer functions (such as lighting control, amenities
such as Do Not Disturb and Make Up Room, and general purpose functionality) are required.
Six segmented slider layout
This layout segments the slider into six evenly distributed discrete sensor locations in software using a
unified hardware layout. In Figure 3, the six-sensor layout makes use of the corresponding Blue LEDs. In
the six-sensor configuration, the LEDs change from array functionality to indicator functionality. This
This layout segments the slider into six evenly distributed discrete sensor locations in software using a
unified hardware layout. In Figure 3, the six-sensor layout makes use of the corresponding Blue LEDs. In
the six-sensor configuration, the LEDs change from array functionality to indicator functionality. This