The following options are currently available for haptic feedback in rules.mk
:
HAPTIC_ENABLE = yes
HAPTIC_DRIVER += DRV2605L
HAPTIC_DRIVER += SOLENOID
The following config.h
settings are available for all types of haptic feedback:
Settings | Default | Description |
---|---|---|
HAPTIC_ENABLE_PIN |
Not defined | Configures a pin to enable a boost converter for some haptic solution, often used with solenoid drivers. |
HAPTIC_ENABLE_PIN_ACTIVE_LOW |
Not defined | If defined then the haptic enable pin is active-low. |
HAPTIC_ENABLE_STATUS_LED |
Not defined | Configures a pin to reflect the current enabled/disabled status of haptic feedback. |
HAPTIC_ENABLE_STATUS_LED_ACTIVE_LOW |
Not defined | If defined then the haptic status led will be active-low. |
HAPTIC_OFF_IN_LOW_POWER |
0 |
If set to 1 , haptic feedback is disabled before the device is configured, and while the device is suspended. |
Name | Description |
---|---|
LV061228B-L65-A | z-axis 2v LRA |
Mini Motor Disc | small 2-5v ERM |
Not all keycodes below will work depending on which haptic mechanism you have chosen.
Name | Description |
---|---|
HPT_ON |
Turn haptic feedback on |
HPT_OFF |
Turn haptic feedback off |
HPT_TOG |
Toggle haptic feedback on/off |
HPT_RST |
Reset haptic feedback config to default |
HPT_FBK |
Toggle feedback to occur on keypress, release or both |
HPT_BUZ |
Toggle solenoid buzz on/off |
HPT_MODI |
Go to next DRV2605L waveform |
HPT_MODD |
Go to previous DRV2605L waveform |
HPT_CONT |
Toggle continuous haptic mode on/off |
HPT_CONI |
Increase DRV2605L continous haptic strength |
HPT_COND |
Decrease DRV2605L continous haptic strength |
HPT_DWLI |
Increase Solenoid dwell time |
HPT_DWLD |
Decrease Solenoid dwell time |
First you will need a build a circuit to drive the solenoid through a mosfet as most MCU will not be able to provide the current needed to drive the coil in the solenoid.
Wiring diagram provided by Adafruit
Settings | Default | Description |
---|---|---|
SOLENOID_PIN |
Not defined | Configures the pin that the Solenoid is connected to. |
SOLENOID_PIN_ACTIVE_LOW |
Not defined | If defined then the solenoid trigger pin is active low. |
SOLENOID_DEFAULT_DWELL |
12 ms |
Configures the default dwell time for the solenoid. |
SOLENOID_MIN_DWELL |
4 ms |
Sets the lower limit for the dwell. |
SOLENOID_MAX_DWELL |
100 ms |
Sets the upper limit for the dwell. |
SOLENOID_DWELL_STEP_SIZE |
1 ms |
The step size to use when HPT_DWL* keycodes are sent |
SOLENOID_DEFAULT_BUZZ |
0 (disabled) |
On HPT_RST buzz is set "on" if this is "1" |
SOLENOID_BUZZ_ACTUATED |
SOLENOID_MIN_DWELL |
Actuated-time when the solenoid is in buzz mode |
SOLENOID_BUZZ_NONACTUATED |
SOLENOID_MIN_DWELL |
Non-Actuated-time when the solenoid is in buzz mode |
- If solenoid buzz is off, then dwell time is how long the "plunger" stays activated. The dwell time changes how the solenoid sounds.
- If solenoid buzz is on, then dwell time sets the length of the buzz, while
SOLENOID_BUZZ_ACTUATED
andSOLENOID_BUZZ_NONACTUATED
set the (non-)actuation times withing the buzz period. - With the current implementation, for any of the above time settings, the precision of these settings may be affected by how fast the keyboard is able to scan the matrix.
Therefore, if the keyboards scanning routine is slow, it may be preferable to set
SOLENOID_DWELL_STEP_SIZE
to a value slightly smaller than the time it takes to scan the keyboard.
Beware that some pins may be powered during bootloader (ie. A13 on the STM32F303 chip) and will result in the solenoid kept in the on state through the whole flashing process. This may overheat and damage the solenoid. If you find that the pin the solenoid is connected to is triggering the solenoid during bootloader/DFU, select another pin.
DRV2605L is controlled over i2c protocol, and has to be connected to the SDA and SCL pins, these varies depending on the MCU in use.
This driver supports 2 different feedback motors. Set the following in your config.h
based on which motor you have selected.
Eccentric Rotating Mass vibration motors (ERM) is motor with a off-set weight attached so when drive signal is attached, the off-set weight spins and causes a sinusoidal wave that translate into vibrations.
#define FB_ERM_LRA 0
#define FB_BRAKEFACTOR 3 /* For 1x:0, 2x:1, 3x:2, 4x:3, 6x:4, 8x:5, 16x:6, Disable Braking:7 */
#define FB_LOOPGAIN 1 /* For Low:0, Medium:1, High:2, Very High:3 */
/* Please refer to your datasheet for the optimal setting for your specific motor. */
#define RATED_VOLTAGE 3
#define V_PEAK 5
Linear resonant actuators (LRA, also know as a linear vibrator) works different from a ERM. A LRA has a weight and magnet suspended by springs and a voice coil. When the drive signal is applied, the weight would be vibrate on a single axis (side to side or up and down). Since the weight is attached to a spring, there is a resonance effect at a specific frequency. This frequency is where the LRA will operate the most efficiently. Refer to the motor's datasheet for the recommanded range for this frequency.
#define FB_ERM_LRA 1
#define FB_BRAKEFACTOR 3 /* For 1x:0, 2x:1, 3x:2, 4x:3, 6x:4, 8x:5, 16x:6, Disable Braking:7 */
#define FB_LOOPGAIN 1 /* For Low:0, Medium:1, High:2, Very High:3 */
/* Please refer to your datasheet for the optimal setting for your specific motor. */
#define RATED_VOLTAGE 2
#define V_PEAK 2.8
#define V_RMS 2.0
#define V_PEAK 2.1
#define F_LRA 205 /* resonance freq */
DRV2605L comes with preloaded library of various waveform sequences that can be called and played. If writing a macro, these waveforms can be played using DRV_pulse(*sequence name or number*)
List of waveform sequences from the datasheet:
seq# | Sequence name | seq# | Sequence name | seq# | Sequence name |
---|---|---|---|---|---|
1 | strong_click | 43 | lg_dblclick_med_60 | 85 | transition_rampup_med_smooth2 |
2 | strong_click_60 | 44 | lg_dblsharp_tick | 86 | transition_rampup_short_smooth1 |
3 | strong_click_30 | 45 | lg_dblsharp_tick_80 | 87 | transition_rampup_short_smooth2 |
4 | sharp_click | 46 | lg_dblsharp_tick_60 | 88 | transition_rampup_long_sharp1 |
5 | sharp_click_60 | 47 | buzz | 89 | transition_rampup_long_sharp2 |
6 | sharp_click_30 | 48 | buzz_80 | 90 | transition_rampup_med_sharp1 |
7 | soft_bump | 49 | buzz_60 | 91 | transition_rampup_med_sharp2 |
8 | soft_bump_60 | 50 | buzz_40 | 92 | transition_rampup_short_sharp1 |
9 | soft_bump_30 | 51 | buzz_20 | 93 | transition_rampup_short_sharp2 |
10 | dbl_click | 52 | pulsing_strong | 94 | transition_rampdown_long_smooth1_50 |
11 | dbl_click_60 | 53 | pulsing_strong_80 | 95 | transition_rampdown_long_smooth2_50 |
12 | trp_click | 54 | pulsing_medium | 96 | transition_rampdown_med_smooth1_50 |
13 | soft_fuzz | 55 | pulsing_medium_80 | 97 | transition_rampdown_med_smooth2_50 |
14 | strong_buzz | 56 | pulsing_sharp | 98 | transition_rampdown_short_smooth1_50 |
15 | alert_750ms | 57 | pulsing_sharp_80 | 99 | transition_rampdown_short_smooth2_50 |
16 | alert_1000ms | 58 | transition_click | 100 | transition_rampdown_long_sharp1_50 |
17 | strong_click1 | 59 | transition_click_80 | 101 | transition_rampdown_long_sharp2_50 |
18 | strong_click2_80 | 60 | transition_click_60 | 102 | transition_rampdown_med_sharp1_50 |
19 | strong_click3_60 | 61 | transition_click_40 | 103 | transition_rampdown_med_sharp2_50 |
20 | strong_click4_30 | 62 | transition_click_20 | 104 | transition_rampdown_short_sharp1_50 |
21 | medium_click1 | 63 | transition_click_10 | 105 | transition_rampdown_short_sharp2_50 |
22 | medium_click2_80 | 64 | transition_hum | 106 | transition_rampup_long_smooth1_50 |
23 | medium_click3_60 | 65 | transition_hum_80 | 107 | transition_rampup_long_smooth2_50 |
24 | sharp_tick1 | 66 | transition_hum_60 | 108 | transition_rampup_med_smooth1_50 |
25 | sharp_tick2_80 | 67 | transition_hum_40 | 109 | transition_rampup_med_smooth2_50 |
26 | sharp_tick3_60 | 68 | transition_hum_20 | 110 | transition_rampup_short_smooth1_50 |
27 | sh_dblclick_str | 69 | transition_hum_10 | 111 | transition_rampup_short_smooth2_50 |
28 | sh_dblclick_str_80 | 70 | transition_rampdown_long_smooth1 | 112 | transition_rampup_long_sharp1_50 |
29 | sh_dblclick_str_60 | 71 | transition_rampdown_long_smooth2 | 113 | transition_rampup_long_sharp2_50 |
30 | sh_dblclick_str_30 | 72 | transition_rampdown_med_smooth1 | 114 | transition_rampup_med_sharp1_50 |
31 | sh_dblclick_med | 73 | transition_rampdown_med_smooth2 | 115 | transition_rampup_med_sharp2_50 |
32 | sh_dblclick_med_80 | 74 | transition_rampdown_short_smooth1 | 116 | transition_rampup_short_sharp1_50 |
33 | sh_dblclick_med_60 | 75 | transition_rampdown_short_smooth2 | 117 | transition_rampup_short_sharp2_50 |
34 | sh_dblsharp_tick | 76 | transition_rampdown_long_sharp1 | 118 | long_buzz_for_programmatic_stopping |
35 | sh_dblsharp_tick_80 | 77 | transition_rampdown_long_sharp2 | 119 | smooth_hum1_50 |
36 | sh_dblsharp_tick_60 | 78 | transition_rampdown_med_sharp1 | 120 | smooth_hum2_40 |
37 | lg_dblclick_str | 79 | transition_rampdown_med_sharp2 | 121 | smooth_hum3_30 |
38 | lg_dblclick_str_80 | 80 | transition_rampdown_short_sharp1 | 122 | smooth_hum4_20 |
39 | lg_dblclick_str_60 | 81 | transition_rampdown_short_sharp2 | 123 | smooth_hum5_10 |
40 | lg_dblclick_str_30 | 82 | transition_rampup_long_smooth1 | ||
41 | lg_dblclick_med | 83 | transition_rampup_long_smooth2 | ||
42 | lg_dblclick_med_80 | 84 | transition_rampup_med_smooth1 |
#define DRV_GREETING *sequence name or number*
If haptic feedback is enabled, the keyboard will vibrate to a specific sequence during startup. That can be selected using the following define:
#define DRV_MODE_DEFAULT *sequence name or number*
This will set what sequence HPT_RST will set as the active mode. If not defined, mode will be set to 1 when HPT_RST is pressed.
This mode sets continuous haptic feedback with the option to increase or decrease strength.
The Haptic Exclusion is implemented as __attribute__((weak)) bool get_haptic_enabled_key(uint16_t keycode, keyrecord_t *record)
in haptic.c. This allows a re-definition at the required level with the specific requirement / exclusion.
With the entry of #define NO_HAPTIC_MOD
in config.h, the following keys will not trigger feedback:
- Usual modifier keys such as Control/Shift/Alt/Gui (For example
KC_LCTL
) MO()
momentary keys. See also Layers.LM()
momentary keys with mod active.LT()
layer tap keys, when held to activate a layer. However when tapped, and the key is quickly released, and sends a keycode, haptic feedback is still triggered.TT()
layer tap toggle keys, when held to activate a layer. However when tappedTAPPING_TOGGLE
times to permanently toggle the layer, on the last tap haptic feedback is still triggered.MT()
mod tap keys, when held to keep a usual modifier key pressed. However when tapped, and the key is quickly released, and sends a keycode, haptic feedback is still triggered. See also Mod-Tap.
With the entry of #define NO_HAPTIC_ALPHA
in config.h, none of the alpha keys (A ... Z) will trigger a feedback.
With the entry of #define NO_HAPTIC_PUNCTUATION
in config.h, none of the following keys will trigger a feedback: Enter, ESC, Backspace, Space, Minus, Equal, Left Bracket, Right Bracket, Backslash, Non-US Hash, Semicolon, Quote, Grave, Comma, Slash, Dot, Non-US Backslash.
With the entry of #define NO_HAPTIC_LOCKKEYS
in config.h, none of the following keys will trigger a feedback: Caps Lock, Scroll Lock, Num Lock.
With the entry of #define NO_HAPTIC_NAV
in config.h, none of the following keys will trigger a feedback: Print Screen, Pause, Insert, Delete, Page Down, Page Up, Left Arrow, Up Arrow, Right Arrow, Down Arrow, End, Home.
With the entry of #define NO_HAPTIC_NUMERIC
in config.h, none of the following keys between 0 and 9 (KC_1 ... KC_0) will trigger a feedback.