Granite Devices Knowledge Wiki - User contributions [en]

File:Wireless Wheel 2 footprint tolerances.pdf

2022-04-27T11:15:42Z

Vsyrjanen: Wireless Wheel 2 footprint and tolerances

== Summary ==
Wireless Wheel 2 footprint and tolerances

== Licensing ==
{{CopyrightByGDAllRightsReserved}}

Simucube Wireless Wheel 2

2021-09-01T12:28:40Z

Vsyrjanen:

{{Infobox
| headerstyle = background:#e84e0f;color:white;
| above = Wireless Wheel 2 Module
| image =[[File:Wireless_Wheel_2_Module.jpg|300px]]
| image2 = [[File:Wireless_Wheel_2_Module_dimensions.png|300px]]
| data2 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Configurable inputs
| label2 = Digital
| data2 = 96
| label3 = Analog
| data3 = 4
}}
| data3 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Antenna
| label2 = Type
| data2 = External (not included)
| label3 = Connector
| data3 = U.FL
| label4 = Frequency (Center/Band)
| data4 = 2.4 GHz
| label5 = Gain (max)
| data5 = 2.14 dBi
}}
| data4 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Electrical specifications
| data2 = {{Infobox
| child = yes
| headerstyle = text-align:left;
| header1= Rechargeable version:
| label2 = Charger input voltage/current
| data2 = 5.0V / 450mA
| label3 = Supported battery chemistry
| data3 = Li-Ion or Li-Po
| label4 = Battery voltage
| data4 = 2.5V – 4.2V
}}
| data3 = {{Infobox
| child = yes
| headerstyle = text-align:left;
| header1= Non-rechargeable version:
| label2 = Input voltage
| data2 = 2.0V – 3.8V
}}
}}
}}
The Simucube Wireless Wheel 2 Module is an upgraded version of the [[SWW|Simucube Wireless wheel module]]. The new module comes in two different versions, which both offer more digital inputs and 4 analog axes. The non-rechargeable version is intended for endurance with a non-rechargeable battery, and the rechargeable version has an in-build charger and a voltage regulator.

=Digital inputs=
Wireless Wheel 2 Module has 98 digital input pins, of which 96 are fully configurable by wheel manufacturers. Two of the pins are reserved for shifter paddles that must be included in every steering wheel. Paddles are mandatory because they are used to connect and disconnect the wheel from Simucube. Each configurable input pin can be used multiple times with different device types. The input pins can also be used as '''''enable pins'''''. These '''''enable pins''''' can be used to enable and disable other devices. This allows for advanced functionalities, e.g., using a physical encoder as 12 virtual encoders using a rotary switch or disabling unintentional center presses in a 5 or 7-way switch.
==Digital input device types==
===Button (regular button)===
The game controller output signal is high if pressed.
===Encoder===
Each detent is shown as a pulse (25ms). The game controller has an output signal for each turning direction.
===Rotary switch===
Maximum of 12 positions. Changing the switch position will send a pulse (100ms) to the corresponding output. 
If the desired functionality is that the output is constantly on, the rotary switch can also be configured as regular buttons. This can also be done in addition to the default functionality if there are enough unused HID pins.

=Analog inputs=
[[file:SLEEP_pin_controlled_output.png|thumbnail|upright|left|SLEEP pin with transistors can be used to turn external devices on and off]]
The wireless module offers an AVCC output pin for analog devices. To reduce power consumption, the AVCC pin is pulsed so that the pin is only turned on when the ADC module is sampling inputs. Output pulses are approximately 2ms long, and the frequency is 100Hz; this means that AVCC is on 20% of the time. Pulses work great with potentiometers, but Hall-effect sensors might not work with pulsed AVCC if Hall-sensor power-on time is too long. As a result, any excess capacitance must be avoided in the AVCC pin. 
The backup option is to provide VCC for Hall-sensors is to power it from the 3.3v VDD pin and use MOSFETs connected to the SLEEP pin so Hall-sensor can be powered off while Wireless Wheel 2 isn’t connected. SLEEP pin is high when Wireless Wheel 2 is connected to Simucube. See the example in the picture.
 

= Battery connections =
Wireless Wheel 2 Module has multiple VIN, GND, BATT, and SW_IN pins for redundancy. It is recommended to tie them together to ensure a reliable connection with the M.2 connector in mechanical shock or shaking.
== Rechargeable version ==
[[file:rechargeable_wheel_example.png|thumbnail|upright|left|Rechargeable example]]
The rechargeable version has a built-in charger circuit and a DC-DC converter to regulate battery voltage to 3.0V. The charger is connected to VIN and should be provided with 5.0V +- 5% with a minimum of 450mA for charging (e.g. using a USB cable). BATT pins are charger output, and the battery should be connected between these and GND. SW_IN is unregulated voltage input for the Module and will provide voltage to the in-built DC-DC converter. The power switch must be connected between SW_IN pins and the positive battery terminal. Installing a power switch between SW_IN and BATT enables charging when the wheel is turned off.
 
== Non-rechargeable version ==
[[file:non-rechargeable_wheel_example.png|thumbnail|upright|left|Non-rechargeable example]]

The non-rechargeable version does not have a charger or DC-DC converter and is intended for non-rechargeable batteries. Due to a non-existing DC-DC converter, all module voltages will be the same as battery voltage. Even though it is possible to connect batteries straight to SW_IN pins to power this version, it is recommended to connect battery positive lead to VIN, which is internally connected to BATT pins in a non-rechargeable version and includes reverse polarity protection. If a power switch is needed, it can be installed on battery leads or between BATT and SW_IN pins. BATT pins should be connected to SW_IN pins to establish power for the module if the power switch is not connected between mentioned pins.
 

= Pinout =
[[File:SWW2_Pin_numbering.png|thumbnail|upright|left|300px|Connector naming and pin numbering]]
Wireless Wheel 2 Module uses M.2 connectors to fit all the I/O pins in a compact, low-profile packet.
All LED pins include a 220 Ohm current limiter resistor.
 
==Left M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| GND || GND || 66 || 67 || AVCC || 3.0 V OUTPUT to analog circuitry Max. 100 mA including VDD current.
|-
| GND || GND || 64 || 65 || AN0 || ADC CH0 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 62 || 63 || AN1 || ADC CH1 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 60 || 61 || AN2 || ADC CH2 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN64 || 58 || 59 || AN3 || ADC CH3 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN63 || 56 || 57 || BTN1 || Input
|-
| Input || BTN62 || 54 || 55 || BTN2 || Input
|-
| Input || BTN61 || 52 || 53 || BTN3 || Input
|-
| Input || BTN60 || 50 || 51 || BTN4 || Input
|-
| Input || BTN89 || 48 || 49 || BTN5 || Input
|-
| Input || BTN58 || 46 || 47 || BTN6 || Input
|-
| Input || BTN57 || 44 || 45 || BTN7 || Input
|-
| Input || BTN56 || 42 || 43 || BTN8 || Input
|-
| Input || BTN55 || 40 || 41 || BTN9 || Input
|-
| Input || BTN54 || 38 || 39 || BTN10 || Input
|-
| Input || BTN53 || 36 || 37 || BTN11 || Input
|-
| Input || BTN52 || 34 || 35 || BTN12 || Input
|-
| Input || BTN51 || 32 || 33 || BTN13 || Input
|-
| Input || BTN50 || 30 || 31 || BTN14 || Input
|-
| Input || BTN49 || 28 || 29 || BTN15 || Input
|-
| GND || GND || 26 || 27 || BTN16 || Input
|-
| Input || BTN80 || 24 || 25 || GND || GND
|-
| Input || BTN78 || 22 || 23 || BTN79 || Input
|-
| Input || BTN76 || 20 || 21 || BTN77 || Input
|-
| Input || BTN74 || 18 || 19 || BTN75 || Input
|-
| Input || BTN72 || 16 || 17 || BTN73 || Input
|-
| Input || BTN70 || 14 || 15 || BTN71 || Input
|-
| Input || BTN68 || 12 || 13 || BTN69 || Input
|-
| Input || BTN66 || 10 || 11 || BTN67 || Input
|-
| Input || BTN17 || 8 || 9 || BTN65 || Input
|-
| Input || BTN19 || 6 || 7 || BTN18 || Input
|-
| Input || BTN32 || 4 || 5 || LED1 || 3.0 V status LED OUTPUT through 220 Ohm series resistor
|-
| Input || BTN30 || 2 || 3 || BTN20 || Input
|-
| - || - || - || 1 || BTN31 || Input
|}

==Right M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| Input || BTN28 || 66 || 67 || BTN29 || Input
|-
| Input || BTN26 || 64 || 65 || BTN27 || Input
|-
| Input || BTN22 || 62 || 63 || BTN25 || Input
|-
| Input || BTN24 || 60 || 61 || BTN21 || Input
|-
| Do not connect || - || 58 || 59 || BTN23 || Input
|-
| Do not connect || - || 56 || 57 || - || Do not connect
|-
| Input || BTN96 || 54 || no | 55 || no | - || no | Do not connect
|-
| Input || BTN95 || 52 || no | 53 || no | - || no | Do not connect
|-
| Input || BTN94 || 50 || no | 51 || no | - || no | Do not connect
|-
| Input || BTN93 || 48 || no | 49 || no | - || no | Do not connect
|-
| Input || BTN92 || 46 || 47 || SLEEP || BP2 module sleep status Active LOW (BP2 sleeps)
|-
| Input || BTN91 || 44 || 45 || TX || LEUART TX signal OUTPUT
|-
| Input || BTN90 || 42 || 43 || RX || LEUART RX signal INPUT
|-
| Input || BTN89 || 40 || 41 || LED2 || 2nd indicator LED OUTPUT 3.0 V through 220 Ohm resistor
|-
| Input || BTN88 || 38 || 39 || PADDLE1 || Paddle input 1 (left)
|-
| Input || BTN87 || 36 || 37 || PADDLE2 || Paddle input 2 (right)
|-
| Input || BTN86 || 34 || 35 || GND || GND
|-
| Input || BTN85 || 32 || 33 || VDD || +3.0 V OUTPUT Max. 100 mA including AVCC current.
|-
| Input || BTN84 || 30 || 31 || BTN33 || Input
|-
| Input || BTN83 || 28 || 29 || BTN34 || Input
|-
| Input || BTN82 || 26 || 27 || BTN35 || Input
|-
| Input || BTN81 || 24 || 25 || BTN36 || Input
|-
| GND || GND || 22 || 23 || BTN37 || Input
|-
| GND || GND || 20 || 21 || BTN38 || Input
|-
| LED indicator for battery charging Connect LED Anode to BATT || LED_CHG || 18 || 19 || BTN39 || Input
|-
| rowspan="2"| SWITCH_IN operating voltage input || SW_IN || 16 || 17 || BTN40 || Input
|-
| SW_IN|| 14 || 15 || BTN41 || Input
|-
| rowspan="2"| LiPO/Ion/battery positive terminal || BATT || 12 || 13 || BTN42 || Input
|-
| BATT || 10 || 11 || BTN43 || Input
|-
| rowspan="2"| GND || GND || 8 || 9 || BTN44 || Input
|-
| GND || 6 || 7 || BTN45 || Input
|-
| rowspan="2"| Voltage INPUT terminal 5.0 V ± 5 % || VIN || 4 || 5 || BTN46 || Input
|-
| VIN || 2 || 3 || BTN47 || Input
|-
| - || - || - || 1 || BTN48 || Input
|}

=Resources=
==Eagle library==
[[Media:wireless_wheel_2_eagle_library.zip|Eagle library of Wireless Wheel 2 Module]]

==3D-model==
[[Media:Wireless_Wheel_2_Module_3d.zip|Wireless Wheel 2 Module 3D model file (.step)]]

=Availability=
Simucube Wireless Wheel 2 modules are not sold directly to customers at the moment. Contact [mailto:sales@granitedevices.com sales@granitedevices.com] for any questions.

[[Category:Hardware]]
[[Category:Simucube_2]]

File:SWW2 Pin numbering.png

2021-09-01T12:19:29Z

Vsyrjanen: File uploaded with MsUpload

File uploaded with MsUpload

Simucube Wireless Wheel 2

2021-08-25T17:13:50Z

Vsyrjanen:

{{Infobox
| headerstyle = background:#e84e0f;color:white;
| above = Wireless Wheel 2 Module
| image =[[File:Wireless_Wheel_2_Module.jpg|300px]]
| image2 = [[File:Wireless_Wheel_2_Module_dimensions.png|300px]]
| data2 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Configurable inputs
| label2 = Digital
| data2 = 96
| label3 = Analog
| data3 = 4
}}
| data3 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Antenna
| label2 = Type
| data2 = External (not included)
| label3 = Connector
| data3 = U.FL
| label4 = Frequency (Center/Band)
| data4 = 2.4 GHz
| label5 = Gain (max)
| data5 = 2.14 dBi
}}
| data4 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Electrical specifications
| data2 = {{Infobox
| child = yes
| headerstyle = text-align:left;
| header1= Rechargeable version:
| label2 = Charger input voltage/current
| data2 = 5.0V / 450mA
| label3 = Supported battery chemistry
| data3 = Li-Ion or Li-Po
| label4 = Battery voltage
| data4 = 2.5V – 4.2V
}}
| data3 = {{Infobox
| child = yes
| headerstyle = text-align:left;
| header1= Non-rechargeable version:
| label2 = Input voltage
| data2 = 2.0V – 3.8V
}}
}}
}}
The Simucube Wireless Wheel 2 Module is an upgraded version of the Simucube Wireless wheel module. New module offers more digital inputs, 4 analog axis, in-build battery charger and voltage regulator.

=Digital inputs=
Wireless Wheel 2 Module has a total of 98 digital input pins in which 96 inputs are fully configurable by wheel manufacturers. 2 pins are reserved for shifter paddles. Shifter paddles are only mandatory devices, and the rest of the pins can be used as needed. Paddles are mandatory, since those are used to connect and disconnect wheel from Simucube. Each configurable IO pin can be used multiple times with different device types. Most of the input devices can also be configured with enable pins. These enable pins can be used to multiplex encoders. For example, one encoder can be configured as 12 different encoders with rotary switch controlling which encoder is used at time. 
'''Possible digital input device types:''' 
'''Button:''' Regular button, game controller holds signal high if button is pressed. 
'''Encoder:''' Each detent from encoder is shown as pulse from game controller. Pulsed game controller signal depends on turning direction. 
'''Rotary switch:''' Maximum of 12 positions. Changing switch position will pulse corresponding output. Rotary switch can also be configured as buttons, if pulsing output is not needed or wanted. 

=Analog inputs=
Wireless module offers AVCC output for analog devices. Output in AVCC is pulsed for lower power consumption and output is on only when the ADC module is sampling inputs. Output pulses are 2ms long and frequency is 100Hz, this means that AVCC is on 20% of the time. 2ms pulses work great with potentiometers, but Hall-effect sensors might not work with pulsed AVCC if Hall-sensor power-on time is too long. One option to provide VCC for Hall-sensor is to power it from Wireless Wheel 2 VDD pin and use MOSFETs connected to SLEEP pin so Hall-sensor can be powered off while Wireless Wheel 2 isn’t connected. SLEEP pin is high when Wireless Wheel 2 is connected to Simucube.
<gallery>
SLEEP_pin_controlled_output.png|SLEEP pin with transistors can be used to turn external devices on and off
</gallery>

= Battery connections =

Wireless Wheel 2 Module has multiple VIN, GND, BATT and SW_IN pin. Module will work with only one of each used, but it is recommended to connect pins together in wheel circuit board. Pins should be tied together to ensure reliable connection with M.2 connector is case of mechanical shock or shaking. 
 Rechargeable version 
Wireless Wheel 2 Module for rechargeable batteries has in-built charger circuit and DC-DC converter to regulate battery voltage to 3.0V. Charger is connected to VIN and should be provided with 5.0V +- 5% with minimum of 450mA for charging. BATT pins are charger output and battery should be connected between these and GND. SW_IN is unregulated voltage input for Wireless Wheel 2 Module and will provide voltage to in-built DC-DC converter. Power switch can be connected between SW_IN pins and positive battery terminal. installing power switch between SW_IN and BATT enable charging when wheel is turned off. 
 Non-rechargeable version 
Wireless Wheel 2 Module version for non-rechargeable batteries does not have charger nor DC-DC converter. Due to non-existing DC-DC converter, modules VDD output is not regulated, and voltage will be same as battery voltage. Even though it is possible to connect batteries straight to SW_IN pins to power this version, it is recommended to connect battery positive lead to VIN instead, since it has reverse polarity protection. VIN is internally connected to BATT pins in non-rechargeable version. If power switch is needed, it can be installed to battery leads or between BATT and SW_IN pins. If power switch is not connected between mentioned pins, BATT pins should be connected to WS_IN pins to ensure power for module. 
<gallery>
rechargeable_wheel_example.png|Rechargeable example
non-rechargeable_wheel_example.png|Non-rechargeable example
</gallery>

= Pinout =
Wireless Wheel 2 Module uses M.2 connectors to fit all the I/O pins in a compact, low-profile packet.
All LED pins include a 220 Ohm current limiter resistor.

==Left M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| GND || GND || 66 || 67 || AVCC || 3.0 V OUTPUT to analog circuitry Max. 100 mA including VDD current.
|-
| GND || GND || 64 || 65 || AN0 || ADC CH0 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 62 || 63 || AN1 || ADC CH1 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 60 || 61 || AN2 || ADC CH2 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN64 || 58 || 59 || AN3 || ADC CH3 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN63 || 56 || 57 || BTN1 || Input
|-
| Input || BTN62 || 54 || 55 || BTN2 || Input
|-
| Input || BTN61 || 52 || 53 || BTN3 || Input
|-
| Input || BTN60 || 50 || 51 || BTN4 || Input
|-
| Input || BTN89 || 48 || 49 || BTN5 || Input
|-
| Input || BTN58 || 46 || 47 || BTN6 || Input
|-
| Input || BTN57 || 44 || 45 || BTN7 || Input
|-
| Input || BTN56 || 42 || 43 || BTN8 || Input
|-
| Input || BTN55 || 40 || 41 || BTN9 || Input
|-
| Input || BTN54 || 38 || 39 || BTN10 || Input
|-
| Input || BTN53 || 36 || 37 || BTN11 || Input
|-
| Input || BTN52 || 34 || 35 || BTN12 || Input
|-
| Input || BTN51 || 32 || 33 || BTN13 || Input
|-
| Input || BTN50 || 30 || 31 || BTN14 || Input
|-
| Input || BTN49 || 28 || 29 || BTN15 || Input
|-
| GND || GND || 26 || 27 || BTN16 || Input
|-
| Input || BTN80 || 24 || 25 || GND || GND
|-
| Input || BTN78 || 22 || 23 || BTN79 || Input
|-
| Input || BTN76 || 20 || 21 || BTN77 || Input
|-
| Input || BTN74 || 18 || 19 || BTN75 || Input
|-
| Input || BTN72 || 16 || 17 || BTN73 || Input
|-
| Input || BTN70 || 14 || 15 || BTN71 || Input
|-
| Input || BTN68 || 12 || 13 || BTN69 || Input
|-
| Input || BTN66 || 10 || 11 || BTN67 || Input
|-
| Input || BTN17 || 8 || 9 || BTN65 || Input
|-
| Input || BTN19 || 6 || 7 || BTN18 || Input
|-
| Input || BTN32 || 4 || 5 || LED1 || 3.0 V status LED OUTPUT through 220 Ohm series resistor
|-
| Input || BTN30 || 2 || 3 || BTN20 || Input
|-
| - || - || - || 1 || BTN31 || Input
|}

==Right M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| Input || BTN28 || 66 || 67 || BTN29 || Input
|-
| Input || BTN26 || 64 || 65 || BTN27 || Input
|-
| Input || BTN22 || 62 || 63 || BTN25 || Input
|-
| Input || BTN24 || 60 || 61 || BTN21 || Input
|-
| Do not connect || - || 58 || 59 || BTN23 || Input
|-
| Do not connect || - || 56 || 57 || - || Do not connect
|-
| Input || BTN96 || 54 || no | 55 || no | - || no | Do not connect
|-
| Input || BTN95 || 52 || no | 53 || no | - || no | Do not connect
|-
| Input || BTN94 || 50 || no | 51 || no | - || no | Do not connect
|-
| Input || BTN93 || 48 || no | 49 || no | - || no | Do not connect
|-
| Input || BTN92 || 46 || 47 || SLEEP || BP2 module sleep status Active LOW (BP2 sleeps)
|-
| Input || BTN91 || 44 || 45 || TX || LEUART TX signal OUTPUT
|-
| Input || BTN90 || 42 || 43 || RX || LEUART RX signal INPUT
|-
| Input || BTN89 || 40 || 41 || LED2 || 2nd indicator LED OUTPUT 3.0 V through 220 Ohm resistor
|-
| Input || BTN88 || 38 || 39 || PADDLE1 || Paddle input 1 (left)
|-
| Input || BTN87 || 36 || 37 || PADDLE2 || Paddle input 2 (right)
|-
| Input || BTN86 || 34 || 35 || GND || GND
|-
| Input || BTN85 || 32 || 33 || VDD || +3.0 V OUTPUT Max. 100 mA including AVCC current.
|-
| Input || BTN84 || 30 || 31 || BTN33 || Input
|-
| Input || BTN83 || 28 || 29 || BTN34 || Input
|-
| Input || BTN82 || 26 || 27 || BTN35 || Input
|-
| Input || BTN81 || 24 || 25 || BTN36 || Input
|-
| GND || GND || 22 || 23 || BTN37 || Input
|-
| GND || GND || 20 || 21 || BTN38 || Input
|-
| LED indicator for battery charging Connect LED Anode to BATT || LED_CHG || 18 || 19 || BTN39 || Input
|-
| rowspan="2"| SWITCH_IN operating voltage input || SW_IN || 16 || 17 || BTN40 || Input
|-
| SW_IN|| 14 || 15 || BTN41 || Input
|-
| rowspan="2"| LiPO/Ion/battery positive terminal || BATT || 12 || 13 || BTN42 || Input
|-
| BATT || 10 || 11 || BTN43 || Input
|-
| rowspan="2"| GND || GND || 8 || 9 || BTN44 || Input
|-
| GND || 6 || 7 || BTN45 || Input
|-
| rowspan="2"| Voltage INPUT terminal 5.0 V ± 5 % || VIN || 4 || 5 || BTN46 || Input
|-
| VIN || 2 || 3 || BTN47 || Input
|-
| - || - || - || 1 || BTN48 || Input
|}

==Resources==
===Eagle library===
[[Media:wireless_wheel_2_eagle_library.zip|Eagle library of Wireless Wheel 2 Module]]

===3D-model===
[[Media:Wireless_Wheel_2_Module_3d.zip|Wireless Wheel 2 Module 3D model file (.step)]]

[[Category:Hardware]]
[[Category:Simucube_2]]

File:Rechargeable wheel example.png

2021-08-25T17:08:09Z

Vsyrjanen: File uploaded with MsUpload

File uploaded with MsUpload

File:Non-rechargeable wheel example.png

2021-08-25T17:08:08Z

Vsyrjanen: File uploaded with MsUpload

File uploaded with MsUpload

Simucube Wireless Wheel 2

2021-08-23T08:17:23Z

Vsyrjanen:

{{Infobox
| headerstyle = background:#e84e0f;color:white;
| above = Wireless Wheel 2 Module
| image =[[File:Wireless_Wheel_2_Module.jpg|300px]]
| image2 = [[File:Wireless_Wheel_2_Module_dimensions.png|300px]]
| data2 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Configurable inputs
| label2 = Digital
| data2 = 96
| label3 = Analog
| data3 = 4
}}
| data3 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Antenna
| label2 = Type
| data2 = External (not included)
| label3 = Connector
| data3 = U.FL
| label4 = Frequency (Center/Band)
| data4 = 2.4 GHz
| label5 = Gain (max)
| data5 = 2.14 dBi
}}
| data4 = {{Infobox
| child = yes
| headerstyle = background:#e84e0f;color:white;
| header1 = Electrical specifications
| data2 = {{Infobox
| child = yes
| headerstyle = text-align:left;
| header1= Rechargeable version:
| label2 = Charger input voltage/current
| data2 = 5.0V / 450mA
| label3 = Supported battery chemistry
| data3 = Li-Ion or Li-Po
| label4 = Battery voltage
| data4 = 2.5V – 4.2V
}}
| data3 = {{Infobox
| child = yes
| headerstyle = text-align:left;
| header1= Non-rechargeable version:
| label2 = Input voltage
| data2 = 2.0V – 3.8V
}}
}}
}}
The Simucube Wireless Wheel 2 Module is an upgraded version of the Simucube Wireless wheel module. New module offers more digital inputs, 4 analog axis, in-build battery charger and voltage regulator.

=Digital inputs=
Wireless Wheel 2 Module has a total of 98 digital input pins in which 96 inputs are fully configurable by wheel manufacturers. 2 pins are reserved for shifter paddles. Shifter paddles are only mandatory devices, and the rest of the pins can be used as needed. Paddles are mandatory, since those are used to connect and disconnect wheel from Simucube. Each configurable IO pin can be used multiple times with different device types. Most of the input devices can also be configured with enable pins. These enable pins can be used to multiplex encoders. For example, one encoder can be configured as 12 different encoders with rotary switch controlling which encoder is used at time. 
'''Possible digital input device types:''' 
'''Button:''' Regular button, game controller holds signal high if button is pressed. 
'''Encoder:''' Each detent from encoder is shown as pulse from game controller. Pulsed game controller signal depends on turning direction. 
'''Rotary switch:''' Maximum of 12 positions. Changing switch position will pulse corresponding output. Rotary switch can also be configured as buttons, if pulsing output is not needed or wanted. 

=Analog inputs=
[[File:SLEEP_pin_controlled_output.png|thumb|right|300px|SLEEP pin with transistors can be used to turn external devices on and off ]]
Wireless module offers AVCC output for analog devices. Output in AVCC is pulsed for lower power consumption and output is on only when the ADC module is sampling inputs. Output pulses are 2ms long and frequency is 100Hz, this means that AVCC is on 20% of the time. 2ms pulses work great with potentiometers, but Hall-effect sensors might not work with pulsed AVCC if Hall-sensor power-on time is too long. One option to provide VCC for Hall-sensor is to power it from Wireless Wheel 2 VDD pin and use MOSFETs connected to SLEEP pin so Hall-sensor can be powered off while Wireless Wheel 2 isn’t connected. SLEEP pin is high when Wireless Wheel 2 is connected to Simucube.

= Pinout =

Wireless Wheel 2 Module uses M.2 connectors to fit all the I/O pins in a compact, low-profile packet.
All LED pins include a 220 Ohm current limiter resistor.

==Left M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| GND || GND || 66 || 67 || AVCC || 3.0 V OUTPUT to analog circuitry Max. 100 mA including VDD current.
|-
| GND || GND || 64 || 65 || AN0 || ADC CH0 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 62 || 63 || AN1 || ADC CH1 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 60 || 61 || AN2 || ADC CH2 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN64 || 58 || 59 || AN3 || ADC CH3 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN63 || 56 || 57 || BTN1 || Input
|-
| Input || BTN62 || 54 || 55 || BTN2 || Input
|-
| Input || BTN61 || 52 || 53 || BTN3 || Input
|-
| Input || BTN60 || 50 || 51 || BTN4 || Input
|-
| Input || BTN89 || 48 || 49 || BTN5 || Input
|-
| Input || BTN58 || 46 || 47 || BTN6 || Input
|-
| Input || BTN57 || 44 || 45 || BTN7 || Input
|-
| Input || BTN56 || 42 || 43 || BTN8 || Input
|-
| Input || BTN55 || 40 || 41 || BTN9 || Input
|-
| Input || BTN54 || 38 || 39 || BTN10 || Input
|-
| Input || BTN53 || 36 || 37 || BTN11 || Input
|-
| Input || BTN52 || 34 || 35 || BTN12 || Input
|-
| Input || BTN51 || 32 || 33 || BTN13 || Input
|-
| Input || BTN50 || 30 || 31 || BTN14 || Input
|-
| Input || BTN49 || 28 || 29 || BTN15 || Input
|-
| GND || GND || 26 || 27 || BTN16 || Input
|-
| Input || BTN80 || 24 || 25 || GND || GND
|-
| Input || BTN78 || 22 || 23 || BTN79 || Input
|-
| Input || BTN76 || 20 || 21 || BTN77 || Input
|-
| Input || BTN74 || 18 || 19 || BTN75 || Input
|-
| Input || BTN72 || 16 || 17 || BTN73 || Input
|-
| Input || BTN70 || 14 || 15 || BTN71 || Input
|-
| Input || BTN68 || 12 || 13 || BTN69 || Input
|-
| Input || BTN66 || 10 || 11 || BTN67 || Input
|-
| Input || BTN17 || 8 || 9 || BTN65 || Input
|-
| Input || BTN19 || 6 || 7 || BTN18 || Input
|-
| Input || BTN32 || 4 || 5 || LED1 || 3.0 V status LED OUTPUT through 220 Ohm series resistor
|-
| Input || BTN30 || 2 || 3 || BTN20 || Input
|-
| - || - || - || 1 || BTN31 || Input
|}

==Right M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| Input || BTN28 || 66 || 67 || BTN29 || Input
|-
| Input || BTN26 || 64 || 65 || BTN27 || Input
|-
| Input || BTN22 || 62 || 63 || BTN25 || Input
|-
| Input || BTN24 || 60 || 61 || BTN21 || Input
|-
| Do not connect || - || 58 || 59 || BTN23 || Input
|-
| Do not connect || - || 56 || 57 || - || Do not connect
|-
| Input || BTN96 || 54 || no | 55 || no | - || no | Do not connect
|-
| Input || BTN95 || 52 || no | 53 || no | - || no | Do not connect
|-
| Input || BTN94 || 50 || no | 51 || no | - || no | Do not connect
|-
| Input || BTN93 || 48 || no | 49 || no | - || no | Do not connect
|-
| Input || BTN92 || 46 || 47 || SLEEP || BP2 module sleep status Active LOW (BP2 sleeps)
|-
| Input || BTN91 || 44 || 45 || TX || LEUART TX signal OUTPUT
|-
| Input || BTN90 || 42 || 43 || RX || LEUART RX signal INPUT
|-
| Input || BTN89 || 40 || 41 || LED2 || 2nd indicator LED OUTPUT 3.0 V through 220 Ohm resistor
|-
| Input || BTN88 || 38 || 39 || PADDLE1 || Paddle input 1 (left)
|-
| Input || BTN87 || 36 || 37 || PADDLE2 || Paddle input 2 (right)
|-
| Input || BTN86 || 34 || 35 || GND || GND
|-
| Input || BTN85 || 32 || 33 || VDD || +3.0 V OUTPUT Max. 100 mA including AVCC current.
|-
| Input || BTN84 || 30 || 31 || BTN33 || Input
|-
| Input || BTN83 || 28 || 29 || BTN34 || Input
|-
| Input || BTN82 || 26 || 27 || BTN35 || Input
|-
| Input || BTN81 || 24 || 25 || BTN36 || Input
|-
| GND || GND || 22 || 23 || BTN37 || Input
|-
| GND || GND || 20 || 21 || BTN38 || Input
|-
| LED indicator for battery charging Connect LED Anode to BATT || LED_CHG || 18 || 19 || BTN39 || Input
|-
| rowspan="2"| SWITCH_IN operating voltage input || BATT || 16 || 17 || BTN40 || Input
|-
| BATT || 14 || 15 || BTN41 || Input
|-
| rowspan="2"| LiPO/Ion/battery positive terminal || BATT+ || 12 || 13 || BTN42 || Input
|-
| BATT+ || 10 || 11 || BTN43 || Input
|-
| rowspan="2"| GND || GND || 8 || 9 || BTN44 || Input
|-
| GND || 6 || 7 || BTN45 || Input
|-
| rowspan="2"| Voltage INPUT terminal 5.0 V ± 5 % || VIN || 4 || 5 || BTN46 || Input
|-
| VIN || 2 || 3 || BTN47 || Input
|-
| - || - || - || 1 || BTN48 || Input
|}

==Resources==
===Eagle library===
[[Media:wireless_wheel_2_eagle_library.zip|Eagle library of Wireless Wheel 2 Module]]

===3D-model===
[[Media:Wireless_Wheel_2_Module_3d.zip|Wireless Wheel 2 Module 3D model file (.step)]]

[[Category:Hardware]]
[[Category:Simucube_2]]

Simucube Wireless Wheel 2

2021-08-20T07:53:22Z

Vsyrjanen:

Simucube Wireless Wheel 2

2021-08-19T13:55:40Z

Vsyrjanen:

File:Wireless Wheel 2 Module dimensions.png

2021-08-19T13:54:30Z

Vsyrjanen: Vsyrjanen uploaded a new version of File:Wireless Wheel 2 Module dimensions.png

File uploaded with MsUpload

Simucube Wireless Wheel 2

2021-08-19T10:54:20Z

Vsyrjanen: /* Resources */

{{Infobox electric device
| name = Wireless Wheel 2 Module
| image =[[File:Wireless_Wheel_2_Module.jpg|300px]]
}}
The Simucube Wireless Wheel 2 Module is an upgraded version of the Simucube Wireless wheel module. New module offers more digital inputs, 4 analog axis, in-build battery charger and voltage regulator.

=Analog inputs=
[[File:SLEEP_pin_controlled_output.png|thumb|right|250px|SLEEP pin with transistors can be used to turn external devices on and off ]]
Wireless module offers AVCC output for analog devices. Output in AVCC is pulsed for lower power consumption and output is on only when the ADC module is sampling inputs. Output pulses are 2ms long and frequency is 100Hz, this means that AVCC is on 20% of the time. 2ms pulses work great with potentiometers, but Hall-effect sensors might not work with pulsed AVCC if Hall-sensor power-on time is too long. One option to provide VCC for Hall-sensor is to power it from Wireless Wheel 2 VDD pin and use MOSFETs connected to SLEEP pin so Hall-sensor can be powered off while Wireless Wheel 2 isn’t connected. SLEEP pin is high when Wireless Wheel 2 is connected to Simucube.

= Pinout =

Wireless Wheel 2 Module uses M.2 connectors to fit all the I/O pins in compact, low-profile packet packet.

==Left M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| GND || GND || 66 || 67 || AVCC || 3.0 V OUTPUT to analog circuitry Max. 100 mA including VDD current.
|-
| GND || GND || 64 || 65 || AN0 || ADC CH0 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 62 || 63 || AN1 || ADC CH1 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 60 || 61 || AN2 || ADC CH2 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN64 || 58 || 59 || AN3 || ADC CH3 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN63 || 56 || 57 || BTN1 || Input
|-
| Input || BTN62 || 54 || 55 || BTN2 || Input
|-
| Input || BTN61 || 52 || 53 || BTN3 || Input
|-
| Input || BTN60 || 50 || 51 || BTN4 || Input
|-
| Input || BTN89 || 48 || 49 || BTN5 || Input
|-
| Input || BTN58 || 46 || 47 || BTN6 || Input
|-
| Input || BTN57 || 44 || 45 || BTN7 || Input
|-
| Input || BTN56 || 42 || 43 || BTN8 || Input
|-
| Input || BTN55 || 40 || 41 || BTN9 || Input
|-
| Input || BTN54 || 38 || 39 || BTN10 || Input
|-
| Input || BTN53 || 36 || 37 || BTN11 || Input
|-
| Input || BTN52 || 34 || 35 || BTN12 || Input
|-
| Input || BTN51 || 32 || 33 || BTN13 || Input
|-
| Input || BTN50 || 30 || 31 || BTN14 || Input
|-
| Input || BTN49 || 28 || 29 || BTN15 || Input
|-
| GND || GND || 26 || 27 || BTN16 || Input
|-
| Input || BTN80 || 24 || 25 || GND || GND
|-
| Input || BTN78 || 22 || 23 || BTN79 || Input
|-
| Input || BTN76 || 20 || 21 || BTN77 || Input
|-
| Input || BTN74 || 18 || 19 || BTN75 || Input
|-
| Input || BTN72 || 16 || 17 || BTN73 || Input
|-
| Input || BTN70 || 14 || 15 || BTN71 || Input
|-
| Input || BTN68 || 12 || 13 || BTN69 || Input
|-
| Input || BTN66 || 10 || 11 || BTN67 || Input
|-
| Input || BTN17 || 8 || 9 || BTN65 || Input
|-
| Input || BTN19 || 6 || 7 || BTN18 || Input
|-
| Input || BTN32 || 4 || 5 || LED1 || 3.0 V status LED OUTPUT through 220 Ohm series resistor
|-
| Input || BTN30 || 2 || 3 || BTN20 || Input
|-
| - || - || - || 1 || BTN31 || Input
|}

==Right M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| Input || BTN28 || 66 || 67 || BTN29 || Input
|-
| Input || BTN26 || 64 || 65 || BTN27 || Input
|-
| Input || BTN22 || 62 || 63 || BTN25 || Input
|-
| Input || BTN24 || 60 || 61 || BTN21 || Input
|-
| Do not connect || - || 58 || 59 || BTN23 || Input
|-
| Do not connect || - || 56 || 57 || - || Do not connect
|-
| Input || BTN96 || 54 || no | 55 || no | - || no | Do not connect
|-
| Input || BTN95 || 52 || no | 53 || no | - || no | Do not connect
|-
| Input || BTN94 || 50 || no | 51 || no | - || no | Do not connect
|-
| Input || BTN93 || 48 || no | 49 || no | - || no | Do not connect
|-
| Input || BTN92 || 46 || 47 || SLEEP || BP2 module sleep status Active LOW (BP2 sleeps)
|-
| Input || BTN91 || 44 || 45 || TX || LEUART TX signal OUTPUT
|-
| Input || BTN90 || 42 || 43 || RX || LEUART RX signal INPUT
|-
| Input || BTN89 || 40 || 41 || LED2 || 2nd indicator LED OUTPUT 3.0 V through 220 Ohm resistor
|-
| Input || BTN88 || 38 || 39 || PADDLE1 || Paddle input 1
|-
| Input || BTN87 || 36 || 37 || PADDLE2 || Paddle input 2
|-
| Input || BTN86 || 34 || 35 || GND || GND
|-
| Input || BTN85 || 32 || 33 || VDD || +3.0 V OUTPUT Max. 100 mA including AVCC current.
|-
| Input || BTN84 || 30 || 31 || BTN33 || Input
|-
| Input || BTN83 || 28 || 29 || BTN34 || Input
|-
| Input || BTN82 || 26 || 27 || BTN35 || Input
|-
| Input || BTN81 || 24 || 25 || BTN36 || Input
|-
| GND || GND || 22 || 23 || BTN37 || Input
|-
| GND || GND || 20 || 21 || BTN38 || Input
|-
| LED indicator for battery charging Connect LED Anode to BATT || LED_CHG || 18 || 19 || BTN39 || Input
|-
| rowspan="2"| SWITCH_IN operating voltage input || BATT || 16 || 17 || BTN40 || Input
|-
| BATT || 14 || 15 || BTN41 || Input
|-
| rowspan="2"| LiPO/Ion/battery positive terminal || BATT+ || 12 || 13 || BTN42 || Input
|-
| BATT+ || 10 || 11 || BTN43 || Input
|-
| rowspan="2"| GND || GND || 8 || 9 || BTN44 || Input
|-
| GND || 6 || 7 || BTN45 || Input
|-
| rowspan="2"| Voltage INPUT terminal 5.0 V ± 5 % || VIN || 4 || 5 || BTN46 || Input
|-
| VIN || 2 || 3 || BTN47 || Input
|-
| - || - || - || 1 || BTN48 || Input
|}

==Resources==
===Eagle library===
[[Media:wireless_wheel_2_eagle_library.zip|Eagle library of Wireless Wheel 2 Module]]

===3D-model===
[[Media:Wireless_Wheel_2_Module_3d.zip|Wireless Wheel 2 Module 3D model file (.step)]]

[[Category:Hardware]]
[[Category:Simucube_2]]

Simucube Wireless Wheel 2

2021-08-19T10:53:46Z

Vsyrjanen: /* Resources */

{{Infobox electric device
| name = Wireless Wheel 2 Module
| image =[[File:Wireless_Wheel_2_Module.jpg|300px]]
}}
The Simucube Wireless Wheel 2 Module is an upgraded version of the Simucube Wireless wheel module. New module offers more digital inputs, 4 analog axis, in-build battery charger and voltage regulator.

=Analog inputs=
[[File:SLEEP_pin_controlled_output.png|thumb|right|250px|SLEEP pin with transistors can be used to turn external devices on and off ]]
Wireless module offers AVCC output for analog devices. Output in AVCC is pulsed for lower power consumption and output is on only when the ADC module is sampling inputs. Output pulses are 2ms long and frequency is 100Hz, this means that AVCC is on 20% of the time. 2ms pulses work great with potentiometers, but Hall-effect sensors might not work with pulsed AVCC if Hall-sensor power-on time is too long. One option to provide VCC for Hall-sensor is to power it from Wireless Wheel 2 VDD pin and use MOSFETs connected to SLEEP pin so Hall-sensor can be powered off while Wireless Wheel 2 isn’t connected. SLEEP pin is high when Wireless Wheel 2 is connected to Simucube.

= Pinout =

Wireless Wheel 2 Module uses M.2 connectors to fit all the I/O pins in compact, low-profile packet packet.

==Left M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| GND || GND || 66 || 67 || AVCC || 3.0 V OUTPUT to analog circuitry Max. 100 mA including VDD current.
|-
| GND || GND || 64 || 65 || AN0 || ADC CH0 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 62 || 63 || AN1 || ADC CH1 INPUT 0 .. 3.0 V voltage range
|-
| GND || GND || 60 || 61 || AN2 || ADC CH2 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN64 || 58 || 59 || AN3 || ADC CH3 INPUT 0 .. 3.0 V voltage range
|-
| Input || BTN63 || 56 || 57 || BTN1 || Input
|-
| Input || BTN62 || 54 || 55 || BTN2 || Input
|-
| Input || BTN61 || 52 || 53 || BTN3 || Input
|-
| Input || BTN60 || 50 || 51 || BTN4 || Input
|-
| Input || BTN89 || 48 || 49 || BTN5 || Input
|-
| Input || BTN58 || 46 || 47 || BTN6 || Input
|-
| Input || BTN57 || 44 || 45 || BTN7 || Input
|-
| Input || BTN56 || 42 || 43 || BTN8 || Input
|-
| Input || BTN55 || 40 || 41 || BTN9 || Input
|-
| Input || BTN54 || 38 || 39 || BTN10 || Input
|-
| Input || BTN53 || 36 || 37 || BTN11 || Input
|-
| Input || BTN52 || 34 || 35 || BTN12 || Input
|-
| Input || BTN51 || 32 || 33 || BTN13 || Input
|-
| Input || BTN50 || 30 || 31 || BTN14 || Input
|-
| Input || BTN49 || 28 || 29 || BTN15 || Input
|-
| GND || GND || 26 || 27 || BTN16 || Input
|-
| Input || BTN80 || 24 || 25 || GND || GND
|-
| Input || BTN78 || 22 || 23 || BTN79 || Input
|-
| Input || BTN76 || 20 || 21 || BTN77 || Input
|-
| Input || BTN74 || 18 || 19 || BTN75 || Input
|-
| Input || BTN72 || 16 || 17 || BTN73 || Input
|-
| Input || BTN70 || 14 || 15 || BTN71 || Input
|-
| Input || BTN68 || 12 || 13 || BTN69 || Input
|-
| Input || BTN66 || 10 || 11 || BTN67 || Input
|-
| Input || BTN17 || 8 || 9 || BTN65 || Input
|-
| Input || BTN19 || 6 || 7 || BTN18 || Input
|-
| Input || BTN32 || 4 || 5 || LED1 || 3.0 V status LED OUTPUT through 220 Ohm series resistor
|-
| Input || BTN30 || 2 || 3 || BTN20 || Input
|-
| - || - || - || 1 || BTN31 || Input
|}

==Right M.2 connector==
{| class="wikitable"
|-
! colspan="3" | Bottom side !! colspan="3" | Top side
|-
! Function !! Signal !! colspan="2" | Pin !! Signal !! Function
|-
| Input || BTN28 || 66 || 67 || BTN29 || Input
|-
| Input || BTN26 || 64 || 65 || BTN27 || Input
|-
| Input || BTN22 || 62 || 63 || BTN25 || Input
|-
| Input || BTN24 || 60 || 61 || BTN21 || Input
|-
| Do not connect || - || 58 || 59 || BTN23 || Input
|-
| Do not connect || - || 56 || 57 || - || Do not connect
|-
| Input || BTN96 || 54 || no | 55 || no | - || no | Do not connect
|-
| Input || BTN95 || 52 || no | 53 || no | - || no | Do not connect
|-
| Input || BTN94 || 50 || no | 51 || no | - || no | Do not connect
|-
| Input || BTN93 || 48 || no | 49 || no | - || no | Do not connect
|-
| Input || BTN92 || 46 || 47 || SLEEP || BP2 module sleep status Active LOW (BP2 sleeps)
|-
| Input || BTN91 || 44 || 45 || TX || LEUART TX signal OUTPUT
|-
| Input || BTN90 || 42 || 43 || RX || LEUART RX signal INPUT
|-
| Input || BTN89 || 40 || 41 || LED2 || 2nd indicator LED OUTPUT 3.0 V through 220 Ohm resistor
|-
| Input || BTN88 || 38 || 39 || PADDLE1 || Paddle input 1
|-
| Input || BTN87 || 36 || 37 || PADDLE2 || Paddle input 2
|-
| Input || BTN86 || 34 || 35 || GND || GND
|-
| Input || BTN85 || 32 || 33 || VDD || +3.0 V OUTPUT Max. 100 mA including AVCC current.
|-
| Input || BTN84 || 30 || 31 || BTN33 || Input
|-
| Input || BTN83 || 28 || 29 || BTN34 || Input
|-
| Input || BTN82 || 26 || 27 || BTN35 || Input
|-
| Input || BTN81 || 24 || 25 || BTN36 || Input
|-
| GND || GND || 22 || 23 || BTN37 || Input
|-
| GND || GND || 20 || 21 || BTN38 || Input
|-
| LED indicator for battery charging Connect LED Anode to BATT || LED_CHG || 18 || 19 || BTN39 || Input
|-
| rowspan="2"| SWITCH_IN operating voltage input || BATT || 16 || 17 || BTN40 || Input
|-
| BATT || 14 || 15 || BTN41 || Input
|-
| rowspan="2"| LiPO/Ion/battery positive terminal || BATT+ || 12 || 13 || BTN42 || Input
|-
| BATT+ || 10 || 11 || BTN43 || Input
|-
| rowspan="2"| GND || GND || 8 || 9 || BTN44 || Input
|-
| GND || 6 || 7 || BTN45 || Input
|-
| rowspan="2"| Voltage INPUT terminal 5.0 V ± 5 % || VIN || 4 || 5 || BTN46 || Input
|-
| VIN || 2 || 3 || BTN47 || Input
|-
| - || - || - || 1 || BTN48 || Input
|}

==Resources==
===Eagle library===
[[Media:wireless_wheel_2_eagle_library.pdf|Eagle library of Wireless Wheel 2 Module]]

===3D-model===
[[Media:Wireless_Wheel_2_Module_3d.zip|Wireless Wheel 2 Module 3D model file (.step)]]

[[Category:Hardware]]
[[Category:Simucube_2]]

File:Wireless wheel 2 eagle library.zip

2021-08-19T10:53:35Z

Vsyrjanen: File uploaded with MsUpload

File uploaded with MsUpload

File:Wireless Wheel 2 Module 3d.zip

2021-08-19T10:53:35Z

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File uploaded with MsUpload

File:Wireless Wheel 2 Module.jpg

2021-08-19T08:00:55Z

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File uploaded with MsUpload

File:Wireless Wheel 2 Module dimensions.png

2021-08-19T08:00:55Z

Vsyrjanen: File uploaded with MsUpload

File uploaded with MsUpload

File:SLEEP pin controlled output.png

2021-08-19T08:00:55Z

Vsyrjanen: File uploaded with MsUpload

File uploaded with MsUpload