This structure defines various settings for the neoVI FIRE2 device.
Remarks
| Item | Description |
|---|---|
perf_en
Performance test. Default value = 0
can1
See CAN_SETTINGS structure
canfd1
See CANFD_SETTINGS structure
can2
See CAN_SETTINGS structure
canfd2
See CANFD_SETTINGS structure
can3
See CAN_SETTINGS structure
canfd3
See CANFD_SETTINGS structure
can4
See CAN_SETTINGS structure
canfd4
See CANFD_SETTINGS structure
can5
See CAN_SETTINGS structure
canfd5
See CANFD_SETTINGS structure
can6
See CAN_SETTINGS structure
canfd6
See CANFD_SETTINGS structure
can7
See CAN_SETTINGS structure
canfd7
See CANFD_SETTINGS structure
can8
See CAN_SETTINGS structure
canfd8
See CANFD_SETTINGS structure
swcan1
See SWCAN_SETTINGS structure
network_enables
Bitfield containing the software license enables. Depending on the hardware license purchased the customer may have to conditionally select which hardware channels to enable. For example the neoVI Red license allows the user to enable any 2 Dual Wire CAN channels and any 2 LIN channels. To enable a specific network its corresponding bit must be set (1). In order to transmit or receive on a network it must be enabled.
swcan2
See SWCAN_SETTINGS structure
network_enables_2
Bitfield containing the software license enables. Depending on the hardware license purchased the customer may have to conditionally select which hardware channels to enable. For example the neoVI Red license allows the user to enable any 2 Dual Wire CAN channels and any 2 LIN channels. To enable a specific network its corresponding bit must be set (1). In order to transmit or receive on a network it must be enabled.
lsftcan1
See CAN_SETTINGS structure
lsftcan2
See CAN_SETTINGS structure
lin1
See LIN_SETTINGS structure
misc_io_initial_ddr
MISC IO Initial Data Direction Register. Controls the initial data direction of the tri-states on all misc digital pins. Each bit corresponds to an individual misc pin. Bit value of 0 signifies an input and bit value 1 signifies and output. Bit values corresponding to non existent pins (EX MISC7-MISC15 on FIRE) have no effect. Default value = 0 Examples: Set MISC1 to be output, all else input: misc_io_initial_ddr = 1 Set MISC1and MISC2 to be output, all else input: misc_io_initial_ddr = 3 (11 binary) Set all MISC pins to output: misc_io_initial_ddr = 65535 (1111111111111111 binary)
lin2
See LIN_SETTINGS structure
misc_io_initial_latch
MISC IO Initial Latch Register. Controls the initial output latch value on all misc digital pins. Each bit corresponds to an individual misc pin. Bit value of 0 signifies an low voltage and bit value 1 signifies high voltage. Bit values corresponding to non existent pins (EX MISC7-MISC15 on FIRE) have no effect. Default value = 0 Examples: Set MISC1 to be high, all else low: misc_io_initial_latch = 1 Set MISC1and MISC2 to be high, all else low: misc_io_initial_latch = 3 (11 binary) Set all MISC pins to high: misc_io_initial_latch = 65535 (1111111111111111 binary) Note: In order for digital outputs to work correctly the corresponding bit in misc_io_initial_ddr must be set to output and corresponding bit in misc_io_analog_enable must be cleared.
lin3
See LIN_SETTINGS structure
misc_io_report_period
Period in milliseconds of device report message holding digital and analog data. Default value = 100 Note: Periodic reporting requires misc_io_on_report_events[0] to be set.
lin4
See LIN_SETTINGS structure
misc_io_on_report_events
Bitfield holding enables for various report triggers for the General IO report. Default value = 0 Bit field values:
lin5
See LIN_SETTINGS structure
misc_io_analog_enable
MISC IO Analog Enable Register. Controls the initial analog enables on all misc analog pins. Each bit corresponds to an individual misc pin that supports analog input. Bit value of 0 signifies that corresponding misc pin is digital only, and bit value 1 signifies corresponding misc pin is analog. Note that because some MISC pins are not capable of analog they are not included in the register. For example neoVI FIRE's analog pins are MISC3-MISC6, therefore bit 0 corresponds to MISC3's analog enable. Bit values corresponding to non existent pins have no effect. Default value = 0 Examples: Set MISC3 to be analog, all else digital. (neoVI FIRE) : misc_io_analog_enable = 1 Set MISC3 and MISC4 to be analog, all else digital. (neoVI FIRE): misc_io_analog_enable = 3 (11 binary) Set all MISC pins to high: misc_io_analog_enable = 65535 (1111111111111111 binary) Note: that in order for analog inputs to work correctly the corresponding bit in misc_io_analog_enable must be set to 1.
ain_sample_period
Controls how long the Analog to Digital Converter samples before preforming a convert in milliseconds. If it is set to zero the hardware will perform the conversion immediately after sampling. This option defaults to 0 but is accessible so that high impedance analog sources can still be used by manually increasing the sample period. Default value = 0
ain_threshold
Percent of full voltage change required to trigger a REPORT_ON_MISCX_AIN event. Valid range is 0-100. Default value = 0 Examples: Report fires every time ADC value changes: ain_threshold = 0 Report fires every time ADC value changes by 400 mV: ain_threshold = 1 Report fires every time ADC value changes by 800 mV: ain_threshold = 2 Report fires every time ADC value changes by 40 V (Unpractical): ain_threshold = 100 Note: Periodic reporting requires proper misc_io_on_report_events bit to be set.
pwr_man_timeout
Number of milliseconds of no bus activity required before neoVI enters low power mode. Note pwr_man_enable must be set for power management to be enabled. Default value = 10000
pwr_man_enable
1 = enable Power Management, 0 = disable. Default value = 0
network_enabled_on_boot
Normally neoVI only initiates its comm channels when CoreMini is running or if neoVI is online with DLL/Vehicle Spy 3. Practically this means the the CAN controllers stay in Listen Only mode until the device goes online. Once online the neoVI loads the user settings. Setting this parameter to 1 will change this behavior so that the neoVI enables its controllers immediately on boot. Default value = 0
iso15765_separation_time_offset
In an ISO15765-2 Transmission, the receiver transmits a flow control message that informs that transmitter how much time there should be between individual CAN messages. This parameter allows the user to shift that spacing to make it smaller or larger. Valid range is -1563 to 1563 units where each unit represents 6.4us. Defaults to 0. If IFS plus the offset is negative than the Tx Messages will be back to back. Default value = 0 Examples: ISO15765-2 Tx Message Inner frame spacing is exactly what is specified in flow control message: iso15765_separation_time_offset = 0 ISO15765-2 Tx Message Inner frame spacing is what's specified in flow control message.+ 998.4 us: iso15765_separation_time_offset = 156 ISO15765-2 Tx Message Inner frame spacing is what's specified in flow control message.- 998.4 us: iso15765_separation_time_offset = -156
iso_9141_kwp_enable_reserved
Reserved
iso9141_kwp_settings_1
See ISO9141_KEYWORD2000_SETTINGS structure
iso_parity_1
ISO9141 Parity setting: 0 - no parity, 1 - even, 2 - odd
iso9141_kwp_settings_2
See ISO9141_KEYWORD2000_SETTINGS structure
iso_parity_2
ISO9141 Parity setting: 0 - no parity, 1 - even, 2 - odd
iso9141_kwp_settings_3
See ISO9141_KEYWORD2000_SETTINGS structure
iso_parity_3
ISO9141 Parity setting: 0 - no parity, 1 - even, 2 - odd
iso9141_kwp_settings_4
See ISO9141_KEYWORD2000_SETTINGS structure
iso_parity_4
ISO9141 Parity setting: 0 - no parity, 1 - even, 2 - odd
iso_msg_termination_1
ISO9141 message termination setting: 0 - use inner frame time 1 - GME CIM-SCL
iso_msg_termination_2
ISO9141 message termination setting: 0 - use inner frame time 1 - GME CIM-SCL
iso_msg_termination_3
ISO9141 message termination setting: 0 - use inner frame time 1 - GME CIM-SCL
iso_msg_termination_4
ISO9141 message termination setting: 0 - use inner frame time 1 - GME CIM-SCL
idle_wakeup_network_enables_1
Bitfield containing list of hardware networks to look at for sleep enable. To enable a specific network its corresponding bit must be set (1). In order to transmit or receive on a network it must be enabled.
idle_wakeup_network_enables_2
Bitfield containing list of hardware networks to look at for sleep enable. To enable a specific network its corresponding bit must be set (1). In order to transmit or receive on a network it must be enabled.
network_enables_3
Bitfield containing the software license enables. Depending on the hardware license purchased the customer may have to conditionally select which hardware channels to enable. For example the neoVI Red license allows the user to enable any 2 Dual Wire CAN channels and any 2 LIN channels. To enable a specific network its corresponding bit must be set (1). In order to transmit or receive on a network it must be enabled.
idle_wakeup_network_enables_3
Bitfield containing list of hardware networks to look at for sleep enable. To enable a specific network its corresponding bit must be set (1). In order to transmit or receive on a network it must be enabled.
can_switch_mode
Not Available
text_api
See STextAPISettings structure
termination_enables
Bitfield containing the termination enables. For the neoVI Fire 2, the termination is grouped into banks. Only 2 form a single bank can be neabled.
lin6
See LIN_SETTINGS structure
ethernet
See ETHERNET_SETTINGS structure
slaveVnetA
Sets the type of VNET is in slot A for ION and Plasma devices eNoVnet = 0 eAinVnet = 1 eFlexRayVnet = 2 eSlaveFireVnet =3 eSlaveFireVnetEP = 4 eSlaveFire2Vnet = 5 eSlaveFire2VnetZ = 6 eSlaveMost150 = 7
slaveVnetB
Sets the type of VNET is in slot B for Plasma devices eNoVnet = 0 eAinVnet = 1 eFlexRayVnet = 2 eSlaveFireVnet =3 eSlaveFireVnetEP = 4 eSlaveFire2Vnet = 5 eSlaveFire2VnetZ = 6 eSlaveMost150 = 7
flags
Bitfield with misc settings for the device. List below gives the parameter with the bit number to have set to enable. Disable USB Check On Boot : 0 Bus Messages To Android (ION and Plasma) : 2
digitalIoThresholdTicks
Ticks needed to trigger digital change
digitalIoThresholdEnable
Enable digital change thresholding
timeSync
See TIMESYNC_ICSHARDWARE_SETTINGS structure
disk
See DISK_SETTINGS structure
ethernet2
See ETHERNET_SETTINGS2 structure
HSCAN : 0
MSCAN : 1
LIN1 : 2
LIN2 : 3
NA : 4
HSCAN2 : 5
LSFTCAN1 : 6
SWCAN1 : 7
HSCAN3 : 8
NA : 9
NA : 10
LIN3 : 11
LIN4 : 12
NA : 13
HSCAN4 : 14
HSCAN5 : 15
KLINE1 : 0
KLINE2 : 1
KLINE3 : 2
KLINE4 : 3
NA : 4
NA : 5
NA : 6
NA : 7
NA : 8
NA : 9
NA : 10
SWCAN2 : 11
ETHERNET_DAQ : 12
ETHERNET : 13
NA : 14
NA : 15
REPORT_ON_PERIODIC : 0
REPORT_ON_MISC1 : 1
REPORT_ON_MISC2 : 2
REPORT_ON_MISC3 : 3
REPORT_ON_MISC4 : 4
REPORT_ON_MISC5 : 5
REPORT_ON_MISC6 : 6
REPORT_ON_LED1 : 7
REPORT_ON_LED2 : 8
REPORT_ON_KLINE : 9
REPORT_ON_MISC3_AIN : 10
REPORT_ON_MISC4_AIN : 11
REPORT_ON_MISC5_AIN : 12
REPORT_ON_MISC6_AIN : 13
HSCAN : 0
MSCAN : 1
LIN1 : 2
LIN2 : 3
NA : 4
HSCAN2 : 5
LSFTCAN1 : 6
SWCAN1 : 7
HSCAN3 : 8
NA : 9
NA : 10
LIN3 : 11
LIN4 : 12
NA : 13
HSCAN4 : 14
HSCAN5 : 15
KLINE1 : 0
KLINE2 : 1
KLINE3 : 2
KLINE4 : 3
NA : 4
NA : 5
NA : 6
NA : 7
NA : 8
NA : 9
NA : 10
SWCAN2 : 11
ETHERNET_DAQ : 12
ETHERNET : 13
NA : 14
NA : 15
HSCAN6 : 0
HSCAN7 : 1
LIN6 : 2
LSFTCAN2 : 3
NA : 4
NA : 5
NA : 6
NA : 7
NA : 8
NA : 9
NA : 10
NA : 11
NA : 12
NA : 13
NA : 14
NA : 15
HSCAN6 : 0
HSCAN7 : 1
LIN6 : 2
LSFTCAN2 : 3
NA : 4
NA : 5
NA : 6
NA : 7
NA : 8
NA : 9
NA : 10
NA : 11
NA : 12
NA : 13
NA : 14
NA : 15
HSCAN (Bank0): 0
MSCAN (Bank1): 1
HSCAN2 (BANK1) : 5
HSCAN3 (Bank0) : 8
HSCAN4 (Bank1): 14
HSCAN5 (Bank0) : 15
HSCAN6 (Bank1) : 32
HSCAN7 (Bank0): 33