(This page is currently under construction and the following informations are preliminary)

1 Generals
- 1.1 Description
- 1.2 SMARC Standard
- 1.3 Block Diagram
2 Features and Interfaces
- 2.1 Features
- 2.2 Processor:
- 2.3 Memory:
- 2.4 Storage:
- 2.5 Wireless:
- 2.6 Power:
- 2.7 Dimensions:
- 2.8 Interfaces / Signals accessible over connector:
3 Technical Documents
4 1 Pin-description
- 4.1 1.1 Pin Description
  - 4.1.1 Table 1: J1600: SMARC connector
  - 4.1.2 Table 2: J400: i.MX 93 JTAG connector:
- 4.2 1.2 Electrical pin information
  - 4.2.1 Table 3: SMARC pin information
5 2. Interfaces
- 5.1 2.1 Power Supply
  - 5.1.1 Table 4: Power Supply pins
- 5.2 2.2 Control signals
  - 5.2.1 Table 5: Control Signal pins
  - 5.2.2 Table 6: Boot Selection configuration
- 5.3 2.3 UART
  - 5.3.1 Table 7: UART pins
- 5.4 2.4 SPI
  - 5.4.1 Table 8: SPI pins
- 5.5 2.5 I2C
  - 5.5.1 Table 9: I2C pins
- 5.6 2.6 I2S
- 5.7 2.7 SD-Card
  - 5.7.1 Table 11: SDIO pins
- 5.8 2.8 USB
  - 5.8.1 Table 12: USB pins
- 5.9 2.9 Ethernet
  - 5.9.1 Table 13: Ethernet pins
- 5.10 2.10 CAN
  - 5.10.1 Table 14: CAN pins
- 5.11 2.11 Display
  - 5.11.1 2.11.1 LVDS-display
  - 5.11.2 Table 15: LVDS pins
  - 5.11.3 2.11.2 MIPI or eDP (optional)
  - 5.11.4 Table 16: MIPI or eDP pins
- 5.12 2.12 Camera
  - 5.12.1 Table 17: Camera pins
- 5.13 2.13 Wireless
- 5.14 2.14 NONE SMARC STANDARD
  - 5.14.1 2.14.1 MQS (Medium Quality Sound)
6 3. Specifications

Generals

Description

The MAURY is powered by NXP i.MX 93 processor, which is designed to meet the latest market requirements of connected streaming audio/video devices, scanning/imaging devices and various devices demanding high-performance and low-power.

The i.MX 93 family of processors features advanced implementation of a dual ARM® Cortex®-A55 core, which operates at speeds of up to 1.7GHz (consumer version) and 1.5GHz (industrial version) integrated with a NPU that accelerates machine learning inference. A general purpose Cortex®-M33 core processor is for real-time and low-power processing. A 32-bit LPDDR4 is used for memory. There are a number of other i.MX 93 interfaces for connecting peripherals, such as displays, cameras, GPS and sensors, which are extended by components already available on the module:

eMMC (up to 64 GByte)
2x 1Gbit Ethernet
TPM
USB 2.0 Hub (4x)
eDP
RTC
EEPROM
WLAN 802.11 a/b/g/n/ac and BT 5.3 Combo module (M.2 1216)

SMARC Standard

The SMARC (“Smart Mobility ARChitecture”) is a versatile small form factor computer Module definition targeting applications that require low power, low costs, and high performance. The Modules will typically use ARM SOCs similar or the same as those used in many familiar devices such as tablet computers and smart phones. Alternative low power SOCs and CPUs, such as tablet oriented x86 devices and other RISC CPUs may be used as well.
The Module power envelope is typically under 6W although designs up to about 15W are possible.

Block Diagram

Simplified Block diagram of MAURY

Features and Interfaces

Features

Processor:

NXP i.MX 93 ARM^® Dual Cortex-A55 @ 1.7GHz (consumer), 1.5GHz (industrial)

NXP i.MX 93 ARM^® Cortex-M33 @ 250MHz

NXP i.MX 93 ARM^® Ethos^TM U-65 microNPU

Memory:

Up to 2GByte of 16-bit LPDDR4-4000

Storage:

Up to 64 GByte eMMC

Wireless:

WLAN 802.11 a/b/g/n/ac

BT 5.3

MicroRF-antenna connector

Power:

PMIC to generate all internal and external voltages from 3.3V up to 5V supply.

Dimensions:

(Length x Width x Height): 82.0 x 50.0 x 5.4 mm

Interfaces / Signals accessible over connector:

Power Supply through 5.0VDC +- 5%, +3.2V_RTC
LVDS single channel up to 720p60
MIPI_DSI or eDP interface (factory alternatives) up to 1080p60
SD 4-bit interface (boot device)
2x Gigabit Ethernet interfaces
1x USB 2.0 OTG port
up to 4x USB 2.0 using optional internal 2.0 Hub
1x I2S port
2x UART (4-wires)
2x UART (2-wires)
2x CAN interfaces
12x GPIOs
1x MIPI_CSI 2 Lanes Camera interface
1x General Purpose I2C Bus
2x PWM ports
TPM

Technical Documents

1 Pin-description

The main connector of the MAURY is the J1600 SMARC connector.

J400 may be used for debugging, programming and testing.

On the top side are UFL antenna connectors for the on-board WLAN + BT chip.

Figure: Connectors

1.1 Pin Description

The following signals are present at the SMARC connector.

Table 1: J1600: SMARC connector

Signal	Pin		Pin	Signal

Signal	Pin	Pin	Signal
		S1	-
SMB_ALERT#	P1	S2	-
GND	P2	S3	GND
-	P3	S4	-
-	P4	S5	I2C1_SCL
-	P5	S6	-
-	P6	S7	I2C1_SDA
-	P7	S8	CSI0_CK_P
-	P8	S9	CSI0_CK_N
GND	P9	S10	GND
-	P10	S11	CSI0_RX0_P
-	P11	S12	CSI0_RX0_N
GND	P12	S13	GND
-	P13	S14	CSI0_RX1_P
-	P14	S15	CSI0_RX1_N
GND	P15	S16	GND
-	P16	S17	GBE1_MDIO_P
-	P17	S18	GBE1_MDIO_N
GND	P18	S19	GBE1_LINK100#
GBEO_MDI3_N	P19	S20	GBE1_MDI1_P
GBEO_MDI3_P	P20	S21	GBE1_MDI1_N
GBEO_LINK100#	P21	S22	GBE1_LINK1000#
GBEO_LINK1000#	P22	S23	GBE1_MDI2_P
GBEO_MDI2_N	P23	S24	GBE1_MDI2_N
GBEO_MDI2_P	P24	S25	GND
GBEO_LINK_ACT#	P25	S26	GBE1_MDI3_P
GBEO_MDI1_N	P26	S27	GBE1_MDI3_N
GBEO_MDI1_P	P27	S28	-
-	P28	S29	-
GBEO_MDI0_N	P29	S30	-
GBEO_MDI0_P	P30	S31	GBE1_LINK_ACT#
-	P31	S32	-
GND	P32	S33	-
-	P33	S34	GND
SDIO_CMD	P34	S35	USB4_DP
SDIO_CD#	P35	S36	USB4_DN
SDIO_CK	P36	S37	-
SDIO_PWR_EN_3V3	P37	S38	-
GND	P38	S39	I2S0_LRCK
SDIO_D0	P39	S40	I2S0_SDOUT
SDIO_D1	P40	S41	I2S0_SDIN
SDIO_D2	P41	S42	I2S0_CK
SDIO_D3	P42	S43	-
SPIO_CS0#	P43	S44	-
SPIO_CK	P44	S45	-
SPIO_DIN	P45	S46	-
SPIO_DO	P46	S47	GND
GND	P47	S48	I2C3_SCL
-	P48	S49	I2C3_SDA
-	P49	S50	I2S2_LRCK
GND	P50	S51	I2S2_SDOUT
-	P51	S52	I2S2_SDIN
-	P52	S53	I2S2_CK
GND	P53	S54	-
-	P54	S55	-
-	P55	S56	-
-	P56	S57	-
-	P57	S58	-
-	P58	S59	-
GND	P59	S60	-
USB0_DP	P60	S61	GND
USB0_DN	P61	S62	-
USB0_EN_OC#	P62	S63	-
USB0_VBUS_DET	P63	S64	GND
USB0_OTG_ID	P64	S65	-
USB1_EXT_DP	P65	S66	-
USB1_EXT_DN	P66	S67	GND
USB1_EN_OC#	P67	S68	USB3_DP
GND	P68	S69	USB3_DN
USB2_DP	P69	S70	GND
USB2_DN	P70	S71	-
USB2_EN_OC#	P71	S72	-
STM32_RST#	P72	S73	GND
-	P73	S74	-
USB3_EN_OC#	P74	S75	-

-	P75	S76	-
USB4_EN_OC#	P76	S77	-
PCIE_B_CKREQ#	P77	S78	-
PCIE_A_CKREQ#	P78	S79	-
GND	P79	S80	GND
-	P80	S81	-
-	P81	S82	-
GND	P82	S83	GND
-	P83	S84	-
-	P84	S85	-
GND	P85	S86	GND
-	P86	S87	-
-	P87	S88	-
GND	P88	S89	GND
-	P89	S90	-
-	P90	S91	-
GND	P91	S92	GND
-	P92	S93	-
-	P93	S94	-
GND	P94	S95	DP0_AUX_SEL
-	P95	S96	-
-	P96	S97	-
GND	P97	S98	DP0_HPD
-	P98	S99	-
-	P99	S100	-
GND	P100	S101	GND
-	P101	S102	-
-	P102	S103	-
GND	P103	S104	-
HDMI_HPD	P104	S105	DP0_AUX+
HDMI_CTRL_CK	P105	S106	DP0_AUX-
HDMI_CTRL_DAT	P106	S107	LCD1_BKLT_EN
DP1_AUX_SEL	P107	S108	EDP_DSI_CLK_P
GPIO0/CAM0_PWR#	P108	S109	EDP_DSI_CLK_N
GPIO1/CAM1_PWR#	P109	S110	GND
GPIO2/CAM0_RST#	P110	S111	EDP_DSI_D0_P
GPIO3/CAM1_RST#	P111	S112	EDP_DSI_D0_N
GPIO4	P112	S113	EDP1_HPD
GPIO5	P113	S114	EDP_DSI_D1_P
GPIO6	P114	S115	EDP_DSI_D1_N
GPIO7	P115	S116	LCD1_VDD_EN
GPIO8	P116	S117	EDP_DSI_D2_P
GPIO9	P117	S118	EDP_DSI_D2_N
GPIO10	P118	S119	GND
GPIO11	P119	S120	EDP_DSI_D3_P
GND	P120	S121	EDP_DSI_D3_N
I2C_PM_CK	P121	S122	LCD1_BKLT_PWM
I2C_PM_DAT	P122	S123	-
BOOT_SEL0#	P123	S124	GND
BOOT_SEL1#	P124	S125	LVDS0_TX0_P
BOOT_SEL2#	P125	S126	LVDS0_TX0_N
RESET_OUT#	P126	S127	LCD0_BKLT_EN
RESET_IN#	P127	S128	LVDS0_TX1_P
POWER_BTN#	P128	S129	LVDS0_TX1_N
SER0_TX	P129	S130	GND
SER0_RX	P130	S131	LVDS0_TX2_P
SER0_RTS#	P131	S132	LVDS0_TX2_N
SER0_CTS#	P132	S133	LCD0_VDD_EN
GND	P133	S134	LVDS0_CK_P
SER1_TX	P134	S135	LVDS0_CK_N
SER1_RX	P135	S136	GND
SER2_TX	P136	S137	LVDS0_TX3_P
SER2_RX	P137	S138	LVDS0_TX3_N
SER2_RTS#	P138	S139	I2C1_SCL
SER2_CTS#	P139	S140	I2C1_SDA
SER3_TX	P140	S141	LCD0_BKLT_PWM
SER3_RX	P141	S142	-
GND	P142	S143	GND
CAN0_TX	P143	S144	EDP0_HPD
CAN0_RX	P144	S145	WDT_TIME_OUT#
CAN1_TX	P145	S146	-
CAN1_RX	P146	S147	VDD_RTC
5V_SLEEP	P147	S148	LID#
5V_SLEEP	P148	S149	SLEEP#
5V_SLEEP	P149	S150	VIN_PWR_BAD#
5V_SLEEP	P150	S151	CHARGING#
5V_SLEEP	P151	S152	CHARGER_PRSNT#
5V_SLEEP	P152	S153	CARRIER_STBY#
5V_SLEEP	P153	S154	CARRIER_PWR_ON
5V_SLEEP	P154	S155	FORCE_RECOV#
5V_SLEEP	P155	S156	BATLOW#
5V_SLEEP	P156	S157	TEST#
		S158	GND

J1600: SMARC connector:

Table 2: J400: i.MX 93 JTAG connector:

This flex-cable connector uses the Seco JTAG connector standard.

Pin	Signal

Pin	Signal
1	1V8_RUN_PTC
2	JTAG_TCK
3	JTAG_TMS
4	JTAG_TDI
5	JTAG_TDO
6	-
7	GND

1.2 Electrical pin information

PI:	Power Input		DO:	Digital Output
PO:	Power Output		DIO:	Digital Input/Output
			DDI:	Differential Input
AI:	Analog Input		DDO:	Differential Output
AO:	Analog Output		DDIO:	Differential Input/Output

DI:	Digital Input		OD	Open-Drain Output

PD:	Pull-Down	(PDp: Pull-Down, Pull-behavior can be changed by software)
PU:	Pull-Up	PUp: Pull-Up, Pull-behavior can be changed by software

If two “types” are specified, the first value determines the type of primary function.

Table 3: SMARC pin information

Pin	Name	Type	Voltage	Connected to

Pin	Name	Type	Voltage	Connected to
P1	SMB_ALERT#	DI, PU(10K)	1V8	STM32, pin M2, port PA5
P2	GND	Ground
P3	-
P4	-
P5	-
P6	-
P7	-
P8	-
P9	GND	Ground
P10	-
P11	-
P12	GND	Ground
P13	-
P14	-
P15	GND	Ground
P16	-
P17	-
P18	GND	Ground
P19	GBEO_MDI3_N	DDIO	3V3	Gbit Ethernet-Phy
P20	GBEO_MDI3_P	DDIO	3V3	Gbit Ethernet-Phy
P21	GBEO_LINK100#	DO, PU(10K)	3V3	Gbit Ethernet-Phy
P22	GBEO_LINK1000#	DO, PU(4K7)	3V3	Gbit Ethernet-Phy
P23	GBEO_MDI2_N	DDIO	3V3	Gbit Ethernet-Phy
P24	GBEO_MDI2_P	DDIO	3V3	Gbit Ethernet-Phy
P25	GBEO_LINK_ACT#	DO, PU(10K)	3V3	Gbit Ethernet-Phy
P26	GBEO_MDI1_N	DDIO	3V3	Gbit Ethernet-Phy
P27	GBEO_MDI1_P	DDIO	3V3	Gbit Ethernet-Phy
P28	-
P29	GBEO_MDI0_N	DDIO	3V3	Gbit Ethernet-Phy
P30	GBEO_MDI0_P	DDIO	3V3	Gbit Ethernet-Phy
P31	-
P32	GND	Ground
P33	-
P34	SDIO_CMD	DO; PU(10K)	1V8 or 3V3	i.MX 93
P35	SDIO_CD#	DI, PU(10K)	1V8 or 3V3	i.MX 93
P36	SDIO_CK	DO, PU(10K)	1V8 or 3V3	i.MX 93
P37	SDIO_PWR_EN_3V3	DO, PU(2K2)	1V8 or 3V3	i.MX 93
P38	GND	Ground
P39	SDIO_D0	DIO	1V8 or 3V3	i.MX 93
P40	SDIO_D1	DIO	1V8 or 3V3	i.MX 93
P41	SDIO_D2	DIO	1V8 or 3V3	i.MX 93
P42	SDIO_D3	DIO	1V8 or 3V3	i.MX 93
P43	SPIO_CS0#	DO	1V8	i.MX 93
P44	SPIO_CK	DO	1V8	i.MX 93
P45	SPIO_DIN	DI	1V8	i.MX 93
P46	SPIO_DO	DO	1V8	i.MX 93
P47	GND	Ground
P48	-
P49	-
P50	GND	Ground
P51	-
P52	-
P53	GND	Ground
P54	-
P55	-
P56	-
P57	-
P58	-
P59	GND	Ground
P60	USB0_DP	DDIO	3V3	i.MX 93
P61	USB0_DN	DDIO	3V3	i.MX 93
P62	USB0_EN_OC#	DI,DO,PU(10K)	1V8	STM32, pin K1, port PC0
P63	USB0_VBUS_DET	DI, PD(10K)	3V3	i.MX 93
P64	USB0_OTG_ID	DI	3V3	i.MX 93
P65	USB1_EXT_DP	DDIO	3V3	USB Hub or i.MX 93 (if no USB Hub)
P66	USB1_EXT_DN	DDIO	3V3	USB Hub or i.MX 93 (if no USB Hub)
P67	USB1_EN_OC#	DI,DO,PU(10K)	1V8	STM32, pin K2, port PC2
P68	GND	Ground
P69	USB2_DP	DDIO	3V3	USB Hub (optional)
P70	USB2_DN	DDIO	3V3	USB Hub (optional)
P71	USB2_EN_OC#	DI,DO,PU(10K)	1V8	STM32, pin L1, port PC3
P72	STM32_RST#	DI, PU(10K)	1V8	STM32, pin G2
P73	-
P74	USB3_EN_OC#	DI,DO,PU(10K)	1V8	STM32, pin M1, port PA2
P75	-
P76	USB4_EN_OC#	DI,DO,PU(10K)	1V8	STM32, pin M3, port PA6
P77	PCIE_B_CKREQ#	DI, DO	1V8	STM32, pin C11, port PA13 used as SWDIO
P78	PCIE_A_CKREQ#	DI	1V8	STM32, pin B12 used as SWCLK
P79	GND	Ground
P80	-
P81	-
P82	GND	Ground
P83	-
P84	-
P85	GND	Ground
P86	-
P87	-
P88	GND	Ground
P89	-
P90	-
P91	GND	Ground
P92	-
P93	-
P94	GND	Ground
P95	-
P96	-
P97	GND	Ground
P98	-
P99	-
P100	GND	Ground
P101	-
P102	-
P103	GND	Ground
P104	HDMI_HPD	PD (1M)		not connected
P105	HDMI_CTRL_CK	PD (100K)		not connected
P106	HDMI_CTRL_DAT	PD (100K)		not connected
P107	DP1_AUX_SEL	PD (1M)		not connected
P108	GPIO0/CAM0_PWR#	DIO	1V8	STM32, Pin H3, Port PF3
P109	GPIO1/CAM1_PWR#	DIO	1V8	STM32, Pin H2, Port PF4
P110	GPIO2/CAM0_RST#	DIO	1V8	STM32, Pin J2, Port PF5
P111	GPIO3/CAM1_RST#	DIO	1V8	STM32, Pin M6, Port PF6
P112	GPIO4	DIO	1V8	STM32, Pin M8, Port PE8
P113	GPIO5	DIO	1V8	STM32, Pin K8, Port PE9
P114	GPIO6	DIO	1V8	STM32, Pin L8, Port PE10
P115	GPIO7	DIO	1V8	STM32, Pin M9, Port PE11
P116	GPIO8	DIO	1V8	STM32, Pin L9, Port PE12
P117	GPIO9	DIO	1V8	STM32, Pin M10, Port PE13
P118	GPIO10	DIO	1V8	STM32, Pin K9, Port PE14
P119	GPIO11	DIO	1V8	STM32, Pin L10, Port PE15
P120	GND	Ground
P121	I2C_PM_CK	DO, PU(4K7)	1V8	STM32, Pin C4, Port PB6
P122	I2C_PM_DAT	DIO, PU(4K7)	1V8	STM32, Pin B3 Port PB7
P123	BOOT_SEL0#	DI, PU(10K)	1V8	STM32, Pin K11, Port PB14
P124	BOOT_SEL1#	DI, PU(10K)	1V8	STM32, Pin G11, Port PD11
P125	BOOT_SEL2#	DI, PU(10K)	1V8	STM32, Pin L11, Port PB11
P126	RESET_OUT#	DO	1V8	STM32, Pin K3, Port PA0
P127	RESET_IN#	DI, PU(10K)	1V8	STM32, Pin E10, Port PA10
P128	POWER_BTN#	DI, PU(10K)	1V8	STM32, Pin M12, Port PB13
P129	SER0_TX	DO	1V8	i.MX 93
P130	SER0_RX	DI, PU(100K)	1V8	i.MX 93
P131	SER0_RTS#	DO	1V8	i.MX 93
P132	SER0_CTS#	DI, PU(100K)	1V8	i.MX 93
P133	GND	Ground
P134	SER1_TX	DO, PU(4K7)	1V8	i.MX 93
P135	SER1_RX	DI, PU(100K)	1V8	i.MX 93
P136	SER2_TX	DO	1V8	i.MX 93
P137	SER2_RX	DI, PU(100K)	1V8	i.MX 93
P138	SER2_RTS#	DO	1V8	i.MX 93
P139	SER2_CTS#	DI, PU(100K)	1V8	i.MX 93
P140	SER3_TX	DO, PU(10K)	1V8	i.MX 93
P141	SER3_RX	DI, PU(100K)	1V8	i.MX 93
P142	GND	Ground
P143	CAN0_TX	DO	1V8	i.MX 93
P144	CAN0_RX	DI	1V8	i.MX 93
P145	CAN1_TX	DO	1V8	i.MX 93
P146	CAN1_RX	DI	1V8	i.MX 93
P147	5V_SLEEP	PI	5V0
P148	5V_SLEEP	PI	5V0
P149	5V_SLEEP	PI	5V0
P150	5V_SLEEP	PI	5V0
P151	5V_SLEEP	PI	5V0
P152	5V_SLEEP	PI	5V0
P153	5V_SLEEP	PI	5V0
P154	5V_SLEEP	PI	5V0
P155	5V_SLEEP	PI	5V0
P156	5V_SLEEP	PI	5V0
S1	-
S2	-
S3	GND	Ground
S4	-
S5	I2C1_SCL	DO, PU(4K7)	1V8	i.MX 93
S6	-
S7	I2C1_SDA	DIO, PU(4K7)	1V8	i.MX 93
S8	CSI0_CK_P	DDI	1V8	i.MX 93
S9	CSI0_CK_N	DDI	1V8	i.MX 93
S10	GND	Ground
S11	CSI0_RX0_P	DDI	1V8	i.MX 93
S12	CSI0_RX0_N	DDI	1V8	i.MX 93
S13	GND	Ground
S14	CSI0_RX1_P	DDI	1V8	i.MX 93
S15	CSI0_RX1_N	DDI	1V8	i.MX 93
S16	GND	Ground
S17	GBE1_MDIO_P	DDIO	3V3	Gbit Ethernet-Phy
S18	GBE1_MDIO_N	DDIO	3V3	Gbit Ethernet-Phy
S19	GBE1_LINK100#	DO, PU(10K)	3V3	Gbit Ethernet-Phy
S20	GBE1_MDI1_P	DDIO	3V3	Gbit Ethernet-Phy
S21	GBE1_MDI1_N	DDIO	3V3	Gbit Ethernet-Phy
S22	GBE1_LINK1000#	DO, PU(4K7)	3V3	Gbit Ethernet-Phy
S23	GBE1_MDI2_P	DDIO	3V3	Gbit Ethernet-Phy
S24	GBE1_MDI2_N	DDIO	3V3	Gbit Ethernet-Phy
S25	GND	Ground
S26	GBE1_MDI3_P	DDIO	3V3	Gbit Ethernet-Phy
S27	GBE1_MDI3_N	DDIO	3V3	Gbit Ethernet-Phy
S28	-
S29	-
S30	-
S31	GBE1_LINK_ACT#	DO, PU(10K)	3V3	Gbit Ethernet-Phy
S32	-
S33	-
S34	GND	Ground
S35	USB4_DP	DDIO	3V3	USB Hub (optional)
S36	USB4_DN	DDIO	3V3	USB Hub (optional)
S37	-
S38	-
S39	I2S0_LRCK	DIO, PU(4K7)	1V8	i.MX 93
S40	I2S0_SDOUT	DO, PU(4K7)	1V8	i.MX 93
S41	I2S0_SDIN	DI	1V8	i.MX 93
S42	I2S0_CK	DO	1V8	i.MX 93
S43	-
S44	-
S45	-
S46	-
S47	GND	Ground
S48	I2C3_SCL	DO, PU(4K7)	1V8	i.MX 93
S49	I2C3_SDA	DIO, PU(4K7)	1V8	i.MX 93
S50	I2S2_LRCK	DIO	1V8	WiFi (optional)
S51	I2S2_SDOUT	DO	1V8	WiFi (optional)
S52	I2S2_SDIN	DI	1V8	WiFi (optional)
S53	I2S2_CK	DO	1V8	WiFi (optional)
S54	-
S55	-
S56	-
S57	-
S58	-
S59	-
S60	-
S61	GND	Ground
S62	-
S63	-
S64	GND	Ground
S65	-
S66	-
S67	GND	Ground
S68	USB3_DP	DDIO	3V3	USB Hub (optional)
S69	USB3_DN	DDIO	3V3	USB Hub (optional)
S70	GND	Ground
S71	-
S72	-
S73	GND	Ground
S74	-
S75	-
S76	-
S77	-
S78	-
S79	-
S80	GND	Ground
S81	-
S82	-
S83	GND	Ground
S84	-
S85	-
S86	GND	Ground
S87	-
S88	-
S89	GND	Ground
S90	-
S91	-
S92	GND	Ground
S93	-
S94	-
S95	DP0_AUX_SEL	PD(1M)		not connected
S96	-
S97	-
S98	DP0_HPD	PD(1M)		not connected
S99	-
S100	-
S101	GND	Ground
S102	-
S103	-
S104	-
S105	DP0_AUX+	PD(100K)		not connected
S106	DP0_AUX-	PU(100K)		not connected
S107	LCD1_BKLT_EN	DO	1V8	STM32, Pin M11, Port PB10
S108	EDP_DSI_CLK_P	DDIO		MIPI to eDP bridge
S109	EDP_DSI_CLK_N	DDIO		MIPI to eDP bridge
S110	GND	Ground
S111	EDP_DSI_D0_P	DDIO		MIPI to eDP bridge
S112	EDP_DSI_D0_N	DDIO		MIPI to eDP bridge
S113	EDP1_HPD	DI, PD(1M)	1V8	MIPI to eDP bridge
S114	EDP_DSI_D1_P	DDIO		MIPI to eDP bridge
S115	EDP_DSI_D1_N	DDIO		MIPI to eDP bridge
S116	LCD1_VDD_EN	DO	1V8	STM32, Pin M5, Port PB1
S117	EDP_DSI_D2_P	DDIO		MIPI to eDP bridge
S118	EDP_DSI_D2_N	DDIO		MIPI to eDP bridge
S119	GND	Ground
S120	EDP_DSI_D3_P	DDIO		MIPI to eDP bridge
S121	EDP_DSI_D3_N	DDIO		MIPI to eDP bridge
S122	LCD1_BKLT_PWM	DO	1V8	STM32, Pin L12, Port PA8
S123	-
S124	GND	Ground
S125	LVDS0_TX0_P	DDIO		i.MX 93
S126	LVDS0_TX0_N	DDIO		i.MX 93
S127	LCD0_BKLT_EN	DO	1V8	STM32, Pin C8, Port PD3
S128	LVDS0_TX1_P	DDIO		i.MX 93
S129	LVDS0_TX1_N	DDIO		i.MX 93
S130	GND	Ground
S131	LVDS0_TX2_P	DDIO		i.MX 93
S132	LVDS0_TX2_N	DDIO		i.MX 93
S133	LCD0_VDD_EN	DO	1V8	STM32, Pin B7, Port B7
S134	LVDS0_CK_P	DDIO		i.MX 93
S135	LVDS0_CK_N	DDIO		i.MX 93
S136	GND	Ground
S137	LVDS0_TX3_P	DDIO		i.MX 93
S138	LVDS0_TX3_N	DDIO		i.MX 93
S139	I2C1_SCL	DO, PU(4K7)	1V8	i.MX 93
S140	I2C1_SDA	DIO, PU(4K7)	1V8	i.MX 93
S141	LCD0_BKLT_PWM	DO	1V8	STM32, Pin K5, Port PA7
S142	-
S143	GND	Ground
S144	EDP0_HPD	PD(1M)		not connected
S145	WDT_TIME_OUT#	DO	1V8	STM32, Pin K12, Port PC7
S146	-
S147	VDD_RTC	PI	3V0
S148	LID#	DI, PU(10K)	1V8	STM32, Pin D12, PA11
S149	SLEEP#	DI, PU(10K)	1V8	STM32, Pin C12, PA12
S150	VIN_PWR_BAD#	DI		Power management
S151	CHARGING#	DI, PU(10K)	1V8	STM32, Pin D10, Port PF8
S152	CHARGER_PRSNT#	DI, PU(10K)	1V8	STM32, Pin H11, Port PD9
S153	CARRIER_STBY#	DO	1V8	STM32, Pin M4, Port PC5
S154	CARRIER_PWR_ON	DO	1V8	STM32, Pin L3, Port PA4
S155	FORCE_RECOV#	DI, PU(10K)	1V8	STM32, Pin H12, Port PD10
S156	BATLOW#	DI, PU(10K)	1V8	STM32, Pin B11, Port PA15
S157	TEST#	DI, PU(10K)	1V8	program mode STM32
S158	GND	Ground

2. Interfaces

This chapter includes a short description of all interfaces of the MAURY. Please consult the processor datasheet for detailed information.

2.1 Power Supply

The MAURY can be supplied by a single +5.0V power supply.

Table 4: Power Supply pins

Name	Description

Name	Description
5V_SLEEP	5V power input. This supply controls the STM32. STM32 MCU controls reset and power to the i.MX 93 processor.
GND	Ground input
VDD_RTC	3V power supply to supply the RTC on the MAURY

2.2 Control signals

Table 5: Control Signal pins

Name	Description

Name	Description
RESET_IN#	Negated reset input. 0: reset device, 1: normal operation
RESET_OUT#	Negated reset output. 0: device in reset, 1: normal operation (active low)
BOOT_SEL[2…0]	tell the module what physical device to do a BCT boot from (see table xxx below)
STM32_RST#	Negated reset input for STM32. 0: reset STM32, 1: normal operation (active low)
POWER_BTN#	Carrier based power button (active low)
WDT_TIME_OUT#	Watchdog output (active low)
LID#	Lid open/close indication input (active low)
SLEEP#	Sleep indicator input (active low)
VIN_PWR_BAD#	Power status input. 0: Carrierrboard power is not ready to support MAURY, 1: Carrierboard power is ready to support MAURY (active low)
CHARGING#	Input, held low by carrier during battery scharging, float when charging is complete (active low)
CHARGER_PRSNT#	Input, held low by Carrier if DC input for battery charger is present (active low)
CARRIER_STBY#	Power status output. If the power save state standby mode is implemented at the Carrier the runtime voltage rails are enabled with this control signal from the module. The module drives this signal high to enable runtime power rails. If no separate standby mode is implemented all rails are enabled with CARRIER_PWR_ON signal. This signal is driven high by the module at runtime. (active low)
CARRIER_PWR_ON	Power status output. It is a signal to Carrier that the Carrier specific power supplies that shall be powered during standby may be enabled. If standby power save state is implemented at the Carrier this signal enables the standby voltage rails.
FORCE_RECOV#	Primary boot media can be re-initialized (active low)
BATLOW#	Input, battery low indication to Module. Carrier to float the line in inactive state (active low)
TEST#	Negated test input of STM32. 0: device in programming mode, 1: normal operation (active low)

Table 6: Boot Selection configuration

	BOOT_SEL2#	BOOT_SEL1#	BOOT_SEL0#	Boot Source

	BOOT_SEL2#	BOOT_SEL1#	BOOT_SEL0#	Boot Source
0	GND	GND	GND	Carrier SATA
1	GND	GND	Float	Carrier SD Card
2	GND	Float	GND	Carrier eSPI
3	GND	Float	Float	Carrier SPI
4	Float	GND	GND	Module device (NAND, NOR)
5	Float	GND	Float	Remote boot (GBE, serial)
6	Float	Float	GND	Module eMMC Flash
7	Float	Float	Float	Module SPI

2.3 UART

The i.MX 93 provides 4 Universal Asynchronous Receiver/Transmitter. With a transceiver these signals can be converted to RS232, RS485 or IrDA.

Following UART ports are accessible through the SMARC connector:

Table 7: UART pins

Name	Description

Name	Description
SER0_TX	Serial 0 transmit output
SER0_RX	Serial 0 receive input
SER0_RTS#	Serial 0 request to send output (active low)
SER0_CTS#	Serial 0 clear to send input (active low)
SER1_TX	Serial 1 transmit output
SER1_RX	Serial 1 receive input
SER2_TX	Serial 2 transmit output
SER2_RX	Serial 2 receive input
SER2_RTS#	Serial 2 request to send output (active low)
SER2_CTS#	Serial 2 clear to send input (active low)
SER3_TX	Serial 3 transmit output
SER3_RX	Serial 3 receive input

Baudrate: High-speed TIA/EIA-232-F compatible, up to 1Mbit/s, IrDA-compatible, up to 115.2 Kbit/s

Data-Bits: 7 or 8 bits (RS232) or 9 bit (RS485)

Stop Bits: 1, 2

Parity: None, Even, Odd

Features: Hardware flow control (RTS, CTS)

2.4 SPI

The serial peripheral interface is a programmable synchronous serial port, which may be used to connect to a multiple of different peripherals.

Table 8: SPI pins

Name	Description

Name	Description
SPIO_CS0#	SPI 0 slave select
SPI0_CK	SPI 0 clock
SPI0_DIN	SPI 0 data in
SPI0_DO	SPI 0 data out

Speed: up to xxx MHz

2.5 I²C

The Inter-Integrated Circuit (I²C ) provides functionality of a standard I²C master and slave.

Table 9: I²C pins

Name	Description

Name	Description
I2C1_SCL	I2C1 clock
I2C1_SDA	I2C1 data
I2C3_SCL	I2C3 clock
I2C3_SDA	I2C3 data
I2C_PM_CK	I2C PM clock
I2C_PM_DAT	I2C PM data

Speed: Standard mode, up to 100kbit/s
Fast mode, up to 400 kbit/s

Features: Multimaster operation.
I²C Bus specification version 2.1

2.6 I²S

The Inter-IC sound interface provides a synchronous audio interface (SAI) and is used to connect to audio codecs.

Table 10: I²S pins

Name	Description

Name	Description
I2S0_LRCK	I2S0 Left & Right Synchronisation Clock
I2S0_SDOUT	I2S0 Digital Audio Output
I2S0_SDIN	I2S0 Digital Audio Input
I2S0_CK	I2S0 Digital Audio Clock
I2S2_LRCK	I2S2 Left & Right Synchronisation Clock
I2S2_SDOUT	I2S2 Digital Audio Output
I2S2_SDIN	I2S2 Digital Audio Input
I2S2_CK	I2S2 Digital Audio Clock

2.7 SD-Card

The SD-Card interface may be used to connect a SD-Card, eMMC or SDIO hardware.

Table 11: SDIO pins

Name	Description

Name	Description
SDIO_CMD	SDIO command output
SDIO_CD#	SDIO card detect input (active low)
SDIO_CK	SDIO clk output
SDIO_PWR_EN_3V3	SDIO Power enable signal
SDIO_D0	SDIO data bit 0
SDIO_D1	SDIO data bit 1
SDIO_D2	SDIO data bit 2
SDIO_D3	SDIO data bit 3

Speed: Card bus clock frequency up to 208 MHz

Features: Conforms to the SD Host Controller Standard Specification version 3.0.

Compatible with the MMC System Specification version 4.2/4.3/4.4/4.41/5.0.
Compatible with the SD Memory Card Specification version 3.0 and supports the Extended Capacity SD Memory Card
Compatible with the SDIO Card Specification version 3.0

2.8 USB

In the standard configuration, the MAURY offers two USB 2.0 ports, which are routed to the SMARC connector. As an assembly option, a quad USB hub is possible, so that up to five USB ports are possible on the SMARC connector.

Table 12: USB pins

Name	Description

Name	Description
USB0_DP	USB0 data (positive)
USB0_DN	USB0 data (negative)
USB0_EN_OC#	USB0 power enable output and overcurrent input (active low)
USB0_VBUS_DET	USB0 VBUS detection
USB0_OTG_ID	USB0 ID detect
USB1_EXT_DP	USB1 data (positive)
USB1_EXT_DN	USB1 data (negative)
USB1_EN_OC#	USB1 power enable output and overcurrent input (active low)
USB2_DP	USB2 data (positive) (optional)
USB2_DN	USB2 data (negative) (optional)
USB2_EN_OC#	USB2 power enable output and overcurrent input (active low) (optional)
USB3_DP	USB3 data (positive) (optional)
USB3_DN	USB3 data (negative) (optional)
USB3_EN_OC#	USB3 power enable output and overcurrent input (active low) (optional)
USB4_DP	USB4 data (positive) (optional)
USB4_DN	USB4 data (negative) (optional)
USB4_EN_OC#	USB4 power enable output and overcurrent input (active low) (optional)

Speed: High-speed 480Mbit/s
Full-speed 12Mbit/s
Low-speed 1.5Mbit/s
Features: Complies with USB specification rev. 2.0

2.9 Ethernet

The MAURY uses two Realtek RTL8211 integrated 10/100/1000 Mbps Ethernet Transceiver to interface with the i.MX 93 RGMII.

Table 13: Ethernet pins

Name	Description

Name	Description
GBE0_MDI0_P	ETH port 0 differential pair 0 positive signal
GBE0_MDI0_N	ETH port 0 differential pair 0 negative signal
GBE0_MDI1_P	ETH port 0 differential pair 1 positive signal
GBE0_MDI1_N	ETH port 0 differential pair 1 negative signal
GBE0_MDI2_P	ETH port 0 differential pair 2 positive signal
GBE0_MDI2_N	ETH port 0 differential pair 2 negative signal
GBE0_MDI3_P	ETH port 0 differential pair 3 positive signal
GBE0_MDI3_N	ETH port 0 differential pair 3 negative signal
GBE0_LINK100#	ETH port 0 Link Speed indication LED for GBE0 100Mbps (active low)
GBE0_LINK1000#	ETH port 0 Link Speed indication LED for GBE0 1000Mbps (active low)
GBE0_LINK_ACT#	ETH port 0 Link / Activity Indication LED driven Low on Link (10, 100 or 1000Mbps) Blinks on Activity (active low)
GBE1_MDI0_P	ETH port 1 differential pair 0 positive signal
GBE1_MDI0_N	ETH port 1 differential pair 0 negative signal
GBE1_MDI1_P	ETH port 1 differential pair 1 positive signal
GBE1_MDI1_N	ETH port 1 differential pair 1 negative signal
GBE1_MDI2_P	ETH port 1 differential pair 2 positive signal
GBE1_MDI2_N	ETH port 1 differential pair 2 negative signal
GBE1_MDI3_P	ETH port 1 differential pair 3 positive signal
GBE1_MDI3_N	ETH port 1 differential pair 3 negative signal
GBE1_LINK100#	ETH port 1 Link Speed indication LED for GBE0 100Mbps (active low)
GBE1_LINK1000#	ETH port 1 Link Speed indication LED for GBE0 1000Mbps (active low)
GBE1_LINK_ACT#	ETH port 1 Link / Activity Indication LED driven Low on Link (10, 100 or 1000Mbps) Blinks on Activity (active low)

2.10 CAN

The CAN interface of the MAURY supports 2x CAN FD.

Table 14: CAN pins

Name	Description

Name	Description
CAN0_TX	CAN 0 transmit data
CAN0_RX	CAN 0 receive data
CAN1_TX	CAN 1 transmit data
CAN1_RX	CAN 1 receive data

2.11 Display

2.11.1 LVDS-display

Table 15: LVDS pins

Name	Description

Name	Description
LVDS0_TX0_P	LVDS port differential pair 0 positive signal
LVDS0_TX0_N	LVDS port differential pair 0 negative signal
LVDS0_TX1_P	LVDS port differential pair 1 positive signal
LVDS0_TX1_N	LVDS port differential pair 1 negative signal
LVDS0_TX2_P	LVDS port differential pair 2 positive signal
LVDS0_TX2_N	LVDS port differential pair 2 negative signal
LVDS0_TX3_P	LVDS port differential pair 3 positive signal
LVDS0_TX3_N	LVDS port differential pair 3 negative signal
LVDS0_CK_P	LVDS port differential clock pair positive signal
LVDS0_CK_N	LVDS port differential clock pair negative signal
LCD0_BKLT_EN	Backlight enable signal
LCD0_BKLT_PWM	Backlight PWM signal
LCD0_VDD_EN	Power control signal

2.11.2 MIPI or eDP (optional)

Table 16: MIPI or eDP pins

Name	Description

Name	Description
EDP_DSI_D0_P	MIPI port differential pair 0 positive signal EDP port differential pair 0 positive signal (optional)
EDP_DSI_D0_N	MIPI port differential pair 0 negative signal EDP port differential pair 0 negative signal (optional)
EDP_DSI_D1_P	MIPI port differential pair 1 positive signal EDP port differential pair 1 positive signal (optional)
EDP_DSI_D1_N	MIPI port differential pair 1 negative signal EDP port differential pair 1 negative signal (optional)
EDP_DSI_D2_P	MIPI port differential pair 2 positive signal EDP port differential pair 2 positive signal (optional)
EDP_DSI_D2_N	MIPI port differential pair 2 negative signal EDP port differential pair 2 negative signal (optional)
EDP_DSI_D3_P	MIPI port differential pair 3 positive signal EDP port differential pair 3 positive signal (optional)
EDP_DSI_D3_N	MIPI port differential pair 3 negative signal EDP port differential pair 3 negative signal (optional)
EDP_DSI_CLK_P	MIPI port differential clock pair positive signal EDP port differential clock pair positive signal (optional)
EDP_DSI_CLK_N	MIPI port differential clock pair negative signal EDP port differential clock pair negative signal (optional)
LCD1_BKLT_EN	Backlight enable signal
LCD1_BKLT_PWM	Backlight PWM signal
LCD1_VDD_EN	Power control signal

2.12 Camera

The i.MX 93 processor got a MIPI CSI camera interface. It is connected to the SMARC connector.

Table 17: Camera pins

Name	Description

Name	Description
CSIO_CK_P	CSI port differential clock pair positive signal
CSIO_CK_N	CSI port differential clock pair negative signal
CSIO_RX0_P	CSI port differential pair 0 positive signal
CSIO_RX0_N	CSI port differential pair 0 negative signal
CSIO_RX1_P	CSI port differential pair 1 positive signal
CSIO_RX1_N	CSI port differential pair 1 negative signal
GPIO0/CAM0_PWR#	Camera 0 power enable signal (active low)
GPIO1/CAM1_PWR#	Camera 1 power enable signal (active low)
GPIO2/CAM0_RST#	Camera 0 reset signal (active low)
GPIO3/CAM1_RST#	Camera 1 reset signal (active low)

Speed:

Features

2.13 Wireless

The MAURY may be equipped with a AzureWave CM276NF WiFi and BT module. The antennas are connected directly to the module.

2.14 NONE SMARC STANDARD

Beyond the SMARC Standard there is the possibility to acces alternative function and Interfaces of the i.MX93. The CPU’s “MUX Mode Select Field” can be used therefore.

2.14.1 MQS (Medium Quality Sound)

The MQS is an audio output which can be used to connect sound speaker or headphones without an additional DAC IC.

MQS1 is accessible over the SMARC Connector.

MQS1_LEFT : CAN0_TX (SMARC P143) or I2S0_LRCK (SMARC S39 )

MQS1_RIGHT: CAN0_RX (SMARC P144) or I2S0_SDIN (SMARC S41 )

MQS2 is accessible over the JTAG Connector J400.

MQS2_LEFT: JTAG_TDI (J400 Pin 4)

MQS2_RIGHT: JTAG_TDO (J400 Pin 5)

3. Specifications

3.1 Absolute Maximum Ratings

Absolute maximum ratings reflect conditions that the module may be exposed outside of the operating limits, without experiencing immediate functional failure. Functional operation is only expected during the conditions indicated under “Recommended Operating Conditions”. Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the module. Exposure to absolute -maximum rated conditions for extended periods may affect device reliability.

	Pin	Min	Max	Unit

	Pin	Min	Max	Unit
Supply Voltage	5V_SLEEP	-0.3	5.5	V
	VDD_RTC	-0.3	3.5	V
Storage Temperature	T_Storage	-40	+85	°C

3.2 Recommended Operating Conditions

	Pin	Min	Typ	Max	Unit

	Pin	Min	Typ	Max	Unit
Supply Voltage	5V_SLEEP	4.75	5.0	5.25	V
	VDD_RTC	2.0	3.0	3.25	V
Supply current (typ.) Power consumption dramatically depends on the usage scenario. This includes things like if the processors operqaating point (ffrequency) can be set to a lower level; if the GPU can be used by an application; the selected display resolution	@ 5V_SLEEP Idle Using/Running Typ. Peak currents when running		tbd tbd tbd		mA mA A
Operating temperature The chip temperature of processor or LPDDR4 might get hotter. The max. case temperature of 1.MX 93 is specified with xxx (consumer) and xxx (industrial). A higher refresh-rate-setting is needed when case temperature of LPDDR4 is expected to rise above xxx . Temperature of eMMC influence the achievable Data Retention	T_Consumer T_Extended T_Industrial	0 -25 -40	+25 +25 +25	+85 +85 +85	°C °C °C

3.3 ESD Ratings (tbd)

		Max	Unit

Max

Unit

V(ESD)
Electrostatic discharge

Human body model (HBM)

Charged-device model (CDM)

+/-1000

+/-250

V

3.4 Electrical characteristics

3.4.1 i.MX 93 GPIO DC parameters. Please view i.MX 93 datasheet for details:

	Parameter	Min	Max	Unit

	Parameter	Min	Max	Unit
V_{IL_1V8}	Low-level input voltage	-0.3	0.3 x V_DD	V
V_{IH_1V8}	High-level input voltage	0.7 x V_DD	VDD + 0.3	V
V_{OL_1V8}	High-level output voltage	0	0.2 x V_DD	V
V_{OH_1V8}	Low-level output voltage	0.8 x V_DD	V_DD	V
R_{P_up}	Pull-Up Resistance	12 (typ 22)	49	kOhm
R_{P_down}	Pull-Down Resistance	13 (typ 23)	48	kOhm

3.4.2 STM32 Cortex M0 GPIO DC parameters. Please view STM32 datasheet for details:

	Parameter	Min	Max	Unit

	Parameter	Min	Max	Unit
V_{IL_1V8}	Low-level input voltage	-	0.3 x V_DDIO	V
V_{IH_1V8}	High-level input voltage	0.7 x x V_DDIO	-	V
V_{OL_1V8}	High-level output voltage	-	0.4	V
V_{OH_1V8}	Low-level output voltage	V_DDIO- 0.45	-	V
R_{P_up}	Pull-Up Resistance	25 (typ 40)	55	kOhm
R_{P_down}	Pull-Down Resistance	25 (typ 40)	55	kOhm

3.5 Mechanical Specification

Dimensions (mm) of the MAURY module (top view)

SOM-SMARC-MX93

Generals

Description

SMARC Standard

Block Diagram

Features and Interfaces

Features

Processor:

Memory:

Storage:

Wireless:

Power:

Dimensions:

Interfaces / Signals accessible over connector:

Technical Documents

1 Pin-description

1.1 Pin Description

Table 1: J1600: SMARC connector

Table 2: J400: i.MX 93 JTAG connector:

1.2 Electrical pin information

Table 3: SMARC pin information

2. Interfaces

2.1 Power Supply

Table 4: Power Supply pins

2.2 Control signals

Table 5: Control Signal pins

Table 6: Boot Selection configuration

2.3 UART

Table 7: UART pins

2.4 SPI

Table 8: SPI pins

2.5 I2C

Table 9: I2C pins

2.6 I2S

2.7 SD-Card

Table 11: SDIO pins

2.8 USB

Table 12: USB pins

2.9 Ethernet

Table 13: Ethernet pins

2.10 CAN

Table 14: CAN pins

2.11 Display

2.11.1 LVDS-display

Table 15: LVDS pins

2.11.2 MIPI or eDP (optional)

Table 16: MIPI or eDP pins

2.12 Camera

Table 17: Camera pins

2.13 Wireless

2.14 NONE SMARC STANDARD

2.14.1 MQS (Medium Quality Sound)

3. Specifications

3.1 Absolute Maximum Ratings

3.2 Recommended Operating Conditions

3.3 ESD Ratings (tbd)

3.4 Electrical characteristics

3.4.1 i.MX 93 GPIO DC parameters. Please view i.MX 93 datasheet for details:

3.4.2 STM32 Cortex M0 GPIO DC parameters. Please view STM32 datasheet for details:

3.5 Mechanical Specification

2.5 I²C

Table 9: I²C pins

2.6 I²S