RZ/G2L and RZ/V2L SOM Hardware User Manual

Revisions and Notes

Date	Owner	Revision	Notes
Oct 11, 2023	Mikhail Anikin	1.0
Oct 16, 2023	Sasha Strizhiver	1.1	general comments
Nov 2, 2023	Shahar Fridman	1.2	Add Power Consumption Measurement
Table of Contents	1 Revisions and Notes 2 Introduction 3 Overview 3.1 Highlighted Features 3.2 Supporting Products 4 Description 4.1 Block Diagram 4.2 Features Summary 5 Core System Components 5.1 RZ/G2L SoC Family 5.2 MEMORIES 5.3 DDR4 5.4 eMMC and SD NAND Memory 5.5 Micro-SD (Carrier) 5.6 Quad Serial NOR Flash (SOM) 5.7 EEPROM (SOM) 5.8 Serial NOR Flash (Carrier) 5.9 10/100/1000 Mbps Ethernet PHY 5.10 WI-FI (802.11AC/A/B/G/N) AND BT 5.3 (MURATA'S CERTIFIED MODULE) 5.11 WI-FI & BT 6 External Interfaces 6.1 General 6.2 USB 2.0 6.3 MIPI CSI 6.4 MIPI DSI 6.5 Parallel Interface 6.6 UART 6.7 SPI 6.8 I2C 6.9 uSD 6.10 CAN-FD 7 CONNECTOR’S SIGNAL DESCRIPTION 7.1 J5001 7.2 J7 7.3 J9 7.4 mikroBUS 7.5 LCD (Parallel Video Output) Signals allocation 8 Power & Reset 8.1 POWER CONSUMPTION 8.1.1 RZ/G2L Power Table 8.1.2 RZ/V2L Power Table 8.2 RESET 9 RZG2L/V2L INTEGRATION MANUAL 9.1 POWER UP SEQUENCE 9.2 BOOTING OPTIONS 9.2.1 Strap pins Booting 9.3 I2C INTERFACES 9.4 GPIO INTERFACES 10 Mechanical Description 11 Documentation 12 Related Articles

Introduction

This User Manual relates to the SolidRun’s RZG2 series, which includes

RZG2L Dual-core ARM A55 (1.2GHz) w Cortex-M33 (200MHz)
RZV2L Dual-core ARM A55 (1.2GHz) w Cortex-M33 (200MHz) and Renesas Original AI Accelerator "DRP-AI"

Overview

The SolidRun’s RZG2L/V2L family is a high-performance 64-Bit Renesas. RZ/G2 Based SOMs with Integrated GPU for Next-Gen Human-Machine Interfaces. RZV2L is adding an AI accelerator to the G2L.

Ideal for automation, smart buildings, network cameras, and IoT devices, SolidRun RZ/G2 SOMs combine a powerful MPU, GPU, extended ECC, Ethernet, and offer long-term Linux software support.

Highlighted Features

Ultra-small footprint SOM (47x30mm) including three board-to-board connectors (250 total pins number).
Renesas’s SoC supports the DUAL version.
- Dual Cortex A55 and up to 1.2GHz
- Cortex-M33 subsystem processor supports real-time tasks.
- Video codec (H.264).
- AI accelerator; DRP-AI (V2L only)
- High-security engines.
- Dual Ethernet interfaces.
- Up to two CAN interfaces.
- High industrial reliability with in-line ECC on DDR4 and on on-chip RAM.
- Single MIPI-CSI and single MIPI-DSI (H.264)
- Optional RGB interface.
- Two USB 2.0.
DDR4 memory in x16 configurations supports up to 2GB and up to 1.6GT/s.
Up to 128GB eMMC.
1Mb QSPI NOR Flash
Wi-Fi 11b/g/n/ac + Bluetooth 5.0 certified module
1Mb QSPI NOR Flash
1Kb I2C EEPROM
Power management devices
Commercial and industrial temperature grade support.

Supporting Products

The following products are provided by SolidRun both as production-level platforms and as reference examples on how to incorporate the SOM in different levels of integration:

HummingBoard Pro – An extended board computer incorporating the SOM with different Linux distributions while adding extra hardware functionalities and access to the hardware.

Description

Block Diagram

The following figure describes the RZ/G2L Blocks Diagram.

Features Summary

Following are the features summary of the SOM. Notice that some of the features are pinout multiplexed (please refer to the pin mux table below and the Renesas datasheets):

Renesas’s RZG2 series SoC (Dual ARM® Cortex™ A55 Processor, up to 1.2 GHz)
Cortex-M33 (200MHz) subsystem processor.
AI accelerator; DRP-AI (V2L only)
Up to 2GByte DDR4 memory and up to 1.6GT/s
Eight bits eMMC 5.1 memory or a four bits SD interface
1Kb I2C EEPROM.
8Mb QSPI NOR Flash.
4-lanes MIPI-DSI interface
Optional RGB (8,8,8) interface.
3D graphics engine (Arm Mali-G31).
Video codec (H.264).
4-lanes MIPI CSI-2
Dual 10/100/1000 Mbps Ethernet PHY
Wi-Fi (802.11a/b/g/n/ac) + BT (5.0) Murata's certified module
Two USB 2.0 Host and Device
Single eSPI interface.
Up to four Serial interfaces.
Up to 2 CAN-FD.
Power:
- A single 5.0V input using B-to-B connector.
- 3.3V/1A output to support carrier's digital interfaces.
- RAA215300 PMIC

Core System Components

RZ/G2L SoC Family

Ideal for automation, smart buildings, network cameras, and IoT devices, SolidRun RZ/G2 SOMs combine a powerful MPU, GPU, extended ECC, Ethernet, and offer long-term Linux software support

A verified Linux Package (VLP) reduces cost and simplifies design.

MEMORIES

The RZG2L SOM supports a variety of memory interfaces for booting and data storage. The following figure describes the RZG2L memory interfaces.

DDR4

Up to 2GB memory space.
16 Bits data bus.
Up to 1600 MT/s.
ECC function for single-bit and double-bit error reporting, single-bit error correction, and programmable removal of ECC storage
Support various low-power modes, clocks, and power-gated operations.
Support Self-Refresh mode.

eMMC and SD NAND Memory

SD0 of the RZG2L/V2L can be configured as an 8-bit eMMC interface or a 4-bit SDIO. Configuration can be done during the boot process (Boot strap pins, SD0_DEV_SEL) or by SW (SD0_DEV_SEL_SW, GPIO_P22_1).

Selecting SD0’s physical connection (eMMC or uSD card) is done by an analog switch.

The state of the analog switch can be set by a DIP-Switch, SW or PU/PD resistors.

eMMC

Up to 128GB memory space.
8 Bits data bus.
Support MMC standard, up to version 4.5.1.
Supports High-speed, HS200 transfer modes
uSDHC-0.
Can be used as BOOT NVM **

Micro-SD (Carrier)

Optional on the carrier board
uSDHC-0.
Implements 4 data bits.
Support SD/SDIO standard up to version 3.0.
SD, SDHC, and SDXC SD memory card access supported.
Default, high-speed, UHS-I/SDR50, and SDR104 transfer modes supported
Can be used as BOOT NVM **

Quad Serial NOR Flash (SOM)

Each channel can be configured as a 1/2/4-bit operation.
Support both SDR (66MHz) mode and DDR (50MHz) mode
No reset
QSPIA/nSS0.
Can be used as BOOT NVM **

EEPROM (SOM)

1Kb EEPROM
ON-Semi’s CAT24AA01TDI or compatible
I2C0
Address 0X50 (7 bits format)
Stores SOM’s configurations.

Serial NOR Flash (Carrier)

Optional on carrier board
1-bit data bus.
eSPI1/nSS0
Can be used as BOOT NVM *

* Note – eMMC and uSD share the same signals.

** Note – Boot configuration is set by the Boot-strap pins

10/100/1000 Mbps Ethernet PHY

The SOM supports two fast Ethernet interfaces.

RGMII interface.
802.3 Ethernet interface for 1000BASE-T, 100BASE-TX, and 10BASE-T.
MaxLinear's MxL86110I PHY.
Auto-MDIX and polarity correction.
Energy-Efficient Ethernet (EEE) and power down mode.
10k byte jumbo frame support.

WI-FI (802.11AC/A/B/G/N) AND BT 5.3 (MURATA'S CERTIFIED MODULE)

WI-FI & BT

The WI-FI & BT module is Murata’s 1MW module Based on Cypress CYW43455 chip. The WI-FI main features are:

Operate at ISM frequency Band (2.4/5 GHz)
IEEE Standards Support 802.11a, 802.11b, 802.11g, 802.11n, 802.11ac
WI-FI over SDIO-1 interface
BT 5.3 BR/EDR/LE
BT over UART-2 Interface
Global certification.

External Interfaces

General

The SOM incorporates three Hirose DF40 board-to-board headers.

The selection of the Hirose DF40 is due to the following criteria:

Miniature (0.4m pitch)
Highly reliable manufacturer
Availability (worldwide distribution channels)
Excellent signal integrity (supports 6Gbps)
- Please contact Hirose or SolidRun for reliability and test result data.
Mating height of between 1.5mm to 4.0mm (1.5mm to 3.0mm if using 70-pin Board-to-Board header). RZG2L/V2L SOM’s headers are fixed, the final mating height is determined by carrier implementation

USB 2.0

The RZG2L/V2L supports two USB 2.0 interfaces. The following figure describes the USB interfaces.

The USB’s main features are:

Single USB 2.0 OTG/DRD(Host/Function) interface (USB0)
Single USB 2.0 Host interface (USB1).
Support mode: High-Speed(480Mbps)/Full-Speed(12Mbps)/Low-Speed(1.5Mbps).
OTG function (Rev2.0).
B2B Connector’s Signal Description
DRD (Dual-Role-Device) function (Static switch between Host and Function).
Power control signals are not part of the USB module, any available GPIO can be used.

Note – The voltage on VBUS is 5V.

MIPI CSI

The following figure describes the CSI interface.

Supports MIPI CSI-2 V2.1 and MIPI D-PHY V2.1 (80 Mbps ~ 1500 Mbps).
Maximum image size: 5 M pixels.
Minimum image size: QVGA (320 × 240) ＝ 76.8 K pixels.
Maximum number of valid pixels in the horizontal direction: 2800 pixels.
Maximum number of valid pixels in the vertical direction: 4095 lines
Support 1/2/4 lanes.
Support 4 Virtual Channel.

MIPI DSI

The following figure describes the DSI interface.

The DSI main features are:

Display Serial Interface Version 1.3.1.
Support up to Full HD (1920 × 1080), 60 fps (RGB888).
Maximum Bandwidth: 1.5 Gbps per lane, 4 data lanes.
Support Output Data Format: RGB666 / RGB888.
Supports 1, 2, 3 and 4 lane configurations.
Support for Virtual Channel

Parallel Interface

Support WXGA (1280x800), 60 fps.
Support Output Data Format: RGB666 / RGB888.
CLK / HD / VD timing signal supported.

UART

Up to 4 UART interfaces. The following figure describes the UART interfaces.

The UART interface's main features are:

UART 2 is connected directly to the WI-FI/BT Modem to support the BT. It is NOT available on the SOM B-t-B connector.
UART 0 supports TX, RX and is used as terminal interface
UART 1 supports TX, RX, CTS and RTS.
UART 3 supports TX and RX.
UART 3 supports TX and RX.
Selectable bit rate with an on-chip baud rate generator.

SPI

Up to 3 SPI interfaces. The following figure describes the eSPI interface.

Single chip select nSS0.
Master/Slave configurable.
Switching of the polarity of the serial transfer clock.
Switching of the clock phase of serial transfer.
Transfer bit-length is selectable as 8, 16, or 32 bits.

I2C

Up to 4 I2C Interfaces. The following figure describes the I2C interfaces.

The I2C main features are:

I2C-3 is used only on the SOM. It is connected to the PMIC.
I2C-0 is available on the connector and connected to the SOM’s EEPROM.
I2C-1 and I2C2 are available on the BtB connectors.
I2C bus format or SMBus format.
Master mode or slave mode selectable
Up to 1 Mbps.
Up to three slave-address settings can be made.
Internal time-out function is capable of detecting long-interval stop of the SCL (clock signal).

uSD

The uSD interface is multiplexed with the eMMC interface. Only one of them is available.

CAN-FD

Up to 2 CANFD interfaces are available. The following figure describes the CAN interfaces.

The CAN main features are:

Supports two interface modes, classical CAN mode and CANFD mode.
ISO11898-1 compliant.
Maximum 1 Mbps in classical CAN mode.
Nominal bit rate: max.1 Mbps, data bit rate: max. 4 Mbps in CANFD mode.

CONNECTOR’S SIGNAL DESCRIPTION

J5001

PIN	HBP 2.5		RZG2L 1.1			PIN	HBP 2.5		RZG2L 1.1

PIN	HBP 2.5		RZG2L 1.1		PIN	HBP 2.5		RZG2L 1.1
1	TP4		NC		2	NC		NC
3	DIP-SWITCH	1V8	MD0	1V8	4	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA3_N
5	DIP-SWITCH	1V	MD1	1V8	6	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA3_P
7	GND		GND		8	GND		GND
9	DSI-CON (J19) or DSI-HDMI		RZ_DSI_CLK_P		10	GND		GND
11	DSI-CON (J19) or DSI-HDMI		RZ_DSI_CLK_N		12	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA0_N
13	GND		GND		14	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA0_P
15	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA2_N		16	GND		GND
17	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA2_P		18	Mini-PCIe (J20, optional)		NC
19	GND		GND		20	Mini-PCIe (J20, optional)		NC
21	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA1_N		22	GND		GND
23	DSI-CON (J19) or DSI-HDMI		RZ_DSI_DATA1_P		24	M.2_W_DIS#	1V8	DISP_DATA15/GPIO_P14_0	3V3
25	GND		GND		26	Mini-PCIe_W_DIS#	3V3	DISP_DATA16/GPIO_P14_1	3V3
27	M.2_WAKW_ON_LAN (PCIe)	NA	GPIO_P19_1	3V3	28	USB1_PWR_EN	3V3	RZ_USB0_VBUSEN	3V3
29	MIKROBUS (J10-4)	NA	RZ_SCIF1_TXD	3V3	30	GND		GND
31	MIKROBUS (J10-3)	NA	RZ_SCIF1_RXD	3V3	32	Mini-PCIe (J20, optional)		NC
33	GND		GND		34	Mini-PCIe (J20, optional)		NC
35	NC		GPIO_P19_0	3V3	36	GND		GND
37	MIKROBUS (J10-1)	NA	RZ_SCIF1_CTS	3V3	38	Mini-PCIe (J20, optional)		NC
39	MIKROBUS (J10-2)	NA	RZ_SCIF1_RTS	3V3	40	Mini-PCIe (J20, optional)		NC
41	HEADER, DIP-SW	3V3	MD2	1V8	42	GND		GND
43	DSI_TS_nINT (DSI-HDMI)	3V3	DISP_DATA5/GPIO_P9_1	3V3	44	LED (D34)	3V3	DISP_DATA0/GPIO_P7_2	3V3
45	NC		DISP_DATA6/GPIO_P10_0	3V3	46	LED (D33)	3V3	GPIO_P48_2	3V3
47	GND		GND		48	LED (D32)	3V3	GPIO_P47_1	3V3
49	NC		GPIO_P40_2	3V3	50	LED (D31)	3V3	GPIO_P47_2	3V3
51	HEADER, DIP-SW	3V3	GPIO_P47_3	3V3	52	GND		GND
53	WIFI_DP (HUB to IMX8M)	NA	ADC_CH0		54	CSI-CON(CON7)		RZ_CSI_DATA0_N
55	WIFI_DN (HUB to IMX8M)	NA	ADC_CH3		56	CSI-CON(CON7)		RZ_CSI_DATA0_P
57	GND		GND		58	GND		GND
59	CSI-CON(CON7)		RZ_CSI_CLK_P		60	CSI-CON(CON7)		RZ_CSI_DATA2_P
61	CSI-CON(CON7)		RZ_CSI_CLK_N		62	CSI-CON(CON7)		RZ_CSI_DATA2_N
63	GND		GND		64	GND		GND
65	CSI-CON(CON7)		RZ_CSI_DATA3_P		66	CSI-CON(CON7)		RZ_CSI_DATA1_P
67	CSI-CON(CON7)		RZ_CSI_DATA3_N		68	CSI-CON(CON7)		RZ_CSI_DATA1_N
69	GND		GND		70	GND		GND

J7

PIN	HBP 2.5		RZG2L 1.1			PIN	HBP 2.5		RZG2L 1.1

PIN	HBP 2.5		RZG2L 1.1		PIN	HBP 2.5		RZG2L 1.1
1	ETH_NIC (Intel, U6)		NC		2	ETH_NIC (Intel, U6)		NC
3	ETH_NIC (Intel, U6)		NC		4	ETH_NIC (Intel, U6)		NC
5	GND		GND		6	GND		GND
7	ETH_NIC (Intel, U6)		NC		8	HEADER (CON4)	NA	NC
9	ETH_NIC (Intel, U6)		NC		10	mPCIe (J20)	3V3	GPIO_P42_2	3V3
11	GND		GND		12	HEADER (CON4)	NA	GPIO_P42_3	3V3
13	M.2_RESET#	1V8	NC		14	POE_AT_DET	3V3	DISP_DATA17/GPIO_P15_0	3V3
15	RTC_CLKO (RTC Int.)	3V3	NC		16	DSI-CON (J19) or DSI-HDMI	NA	DISP_DATA18/GPIO_P15_1	3V3
17	GND		GND		18	M.2_PCIe_3V3_EN	3V3	DISP_DATA21/GPIO_P17_0	3V3
19	HDMI CON (J1)		NC		20	HEADER (CON4)	NA	DISP_DATA22/GPIO_P17_1	3V3
21	HDMI CON (J1)		NC		22	HEADER (CON4)	NA	DISP_DATA23/GPIO_P17_2	3V3
23	GND		GND		24	HEADER (CON4)	NA	DISP_CLK/GPIO_P6_0	3V3
25	HDMI CON (J1)		NC		26	USB-HUB_RST#	3V3	GPIO_P39_1	3V3
27	HDMI CON (J1)		NC		28	HEADER (CON4)	NA	GPIO_P39_2	3V3
29	GND		GND		30	HEADER (CON4)	NA	DISP_HSYNC/GPIO_P6_1	3V3
31	HDMI CON (J1)		NC		32	TP6		DISP_VSYNC/GPIO_P7_0	3V3
33	HDMI CON (J1)		GPIO_P5_1	3V3	34	NC		DISP_DE/GPIO_P7_1	3V3
35	GND		GND		36	HEADER (CON4)	NA	GPIO_P36_1	3V3
37	HDMI CON (J1)		GPIO_P5_2	3V3	38	CSI-CON(CON7)	NA	RZ_SCIF3_TXD	3V3
39	HDMI CON (J1)		GPIO_P5_0	3V3	40	NC		GPIO_P32_1	3V3
41	GND		GND		42	GND		GND
43	HDMI CON (J1)	3V3	DISP_DATA9/GPIO_P11_1	3V3	44	LED (D30)	3V3	RZ_SCIF3_RXD	3V3
45	HDMI CON (J1)	5V	DISP_DATA10/GPIO_P12_0	3V3	46	HEADER (CON4)	NA	GPIO_P33_0	3V3
47	HDMI CON (J1)	5V	DISP_DATA13/GPIO_P13_1	3V3	48	GND		GND
49	HDMI CON (J1)	5V	DISP_DATA14/GPIO_P13_2	3V3	50	HEADER (CON4)	NA	GPIO_P32_0	3V3
51	AUDIO CODEC	3V3	RZ_SSI0_BCK	3V3	52	TERMINAL_TX	3V3	RZ_SCIF0_TXD	3V3
53	AUDIO CODEC	3V3	RZ_SSI0_TXD	3V3	54	TERMINAL_RX	3V3	RZ_SCIF0_RXD	3V3
55	AUDIO CODEC	3V3	RZ_SSI0_RCK	3V3	56	NC		DISP_DATA20/GPIO_P16_1	3V3
57	AUDIO CODEC	3V3	RZ_SSI0_RXD	3V3	58	GND		GND
59	AUDIO CODEC	3V3	DISP_DATA19/GPIO_P16_0	3V3	60	USB-HUB		NC
61	GND		GND		62	USB-HUB		NC
63	HEADER (CON4)	NA	VDD_RTC	3V3	64	GND		GND
65	RESET-B	1V8	SYS_nRST	1V8	66	USB-HUB		NC
67	HEADER (CON4)	NA	ETH1_TRX3_P		68	USB-HUB		NC
69	HEADER (CON4)	NA	ETH1_TRX3_N		70	GND		GND
71	HEADER (CON4)	NA	ETH1_TRX2_P		72	HEADER (CON4)	NA	ETH1_TRX1_P
73	MICRO-SD	NA	ETH1_TRX2_N		74	HEADER (CON4)	NA	ETH1_TRX1_N
75	GND		GND		76	GND		GND
77	HDMI CON (J1)		NC		78	HEADER (CON4)	NA	ETH1_TRX0_P
79	HDMI CON (J1)		NC		80	HEADER (CON4)	NA	ETH1_TRX0_N

J9

PIN	HBP 2.5		RZG2L 1.1			PIN	HBP 2.5		RZG2L 1.1

PIN	HBP 2.5		RZG2L 1.1		PIN	HBP 2.5		RZG2L 1.1
1	ETH-POE		ETH_TRX3_N		2	GND		GND
3	ETH-POE		ETH_TRX3_P		4	USB-TYPE-A		GPIO_P1_0	3V3
5	GND		GND		6	USB-TYPE-A		GPIO_P43_0	3V3
7	ETH-POE		ETH_TRX2_N		8	GND		GND
9	ETH-POE		ETH_TRX2_P		10	USB-TYPE-A		NC
11	GND		GND		12	USB-TYPE-A		RZ_USB1_OVERCUR	3V3
13	ETH-POE		ETH_TRX1_N		14	GND		GND
15	ETH-POE		ETH_TRX1_P		16	USB-TYPE-A		RZ_USB0_DP
17	GND		GND		18	USB-TYPE-A		RZ_USB0_DM
19	ETH-POE		ETH_TRX0_N		20	GND		GND
21	ETH-POE		ETH_TRX0_P		22	USB-HUB		RZ_USB1_DP
23	GND		GND		24	USB-HUB		RZ_USB1_DM
25	ETH-LED		LED_0/PHY_CFG0	3V3	26	GND		GND
27	ETH-LED		LED1_0/PHY_CFG1	3V3	28	M.2_GPS_EN#	NA	RZ_SCIF4_RX	3V3
29	HEADER (CON4)		GPIO_P43_1	3V3	30	J9-59 (BT_FW_FLASH, J9-59)	NA	RZ_SCIF4_TX	3V3
31	MIPI-DSI, ETH-NIC, DSI-CON, CSI-CON, RTC, MIKROBUS	3V3	RZ_RIIC0_SCL	3V3	32	MIKROBUS (J8-3)	NA	RZ_RSPI1_SSL	3V3
33	MIPI-DSI, ETH-NIC, DSI-CON, CSI-CON, RTC, MIKROBUS	3V3	RZ_RIIC0_SDA	3V3	34	CSI-CON (J19) or DSI-HDMI	3V3	RZ_SCIF4_CLK	3V3
35	GND		GND		36	GND		GND
37	USB_HUB_CH1_PWR_EN	3V3	RZ_USB1_VBUSEN	3V3	38	MICRO-SD	SD2	SD_SD0_CLK	SD2
39	J9-55 (BT_FW_FLASH, J9-55)	NA	GPIO_P43_2	3V3	40	MICRO-SD	SD2	SD_SD0_CMD	SD2
41	ETH-NIC RST# (Intel, U6)	3V3	GPIO_P43_3	3V3	42	MICRO-SD	SD2	SD_SD0_DATA0	SD2
43	USB1_VBUS	5V	RZ_USB0_VBUSIN	5V	44	MICRO-SD	SD2	SD_SD0_DATA1	SD2
45	MIKROBUS (J8-5)	NA	RZ_RSPI1_MISO	3V3	46	MICRO-SD	SD2	SD_SD0_DATA2	SD2
47	MIKROBUS (J8-6)	NA	RZ_RSPI1_MOSI	3V3	48	MICRO-SD	SD2	SD_SD0_DATA3	SD2
49	MIKROBUS (J8-4)	NA	RZ_RSPI1_CK	3V3	50	MICRO-SD	SD2	RZ_SD0_CD	SD2
51	AUD_CODEC, USB-TYPEC, USB-HUB	3V3	RZ_RIIC1_SDA	3V3	52	USB-HUB	3V3	RZ_RSPI2_CK	3V3
53	AUD_CODEC, USB-TYPEC, USB-HUB	3V3	RZ_RIIC1_SCL	3V3	54	HEADER, DIP-SW	3V3	RZ_RSPI2_MOSI	3V3
55	BT-FW_FLASH (J9-39)	NA	DISP_DATA8/RZ_CAN0_RX		56	NC		RZ_RSPI2_MISO	3V3
57	HEADER (CON4)	NA	DISP_DATA7/RZ_CAN0_TX		58	NC		RZ_RSPI2_SSL	3V3
59	BT-FW_FLASH (J9-30)	NA	DISP_DATA12/RZ_CAN1_RX		60	NC		RZ_WDTOVF_PERROUT	3V3
61	MICRO-SD		DISP_DATA11/RZ_CAN1_TX		62	PUSH-B		PMIC_PWRON	3V3
63	3V3_IN		3V3_OUT		64	HEADER, DIP-SW	3V3	SD0_DEV_SEL	3V3
65	3V3_IN		3V3_OUT		66	NC		PMIC_EN	3V3
67	3V3_IN		3V3_OUT		68	MICRO-SD	NA	GPIO_SD0_PWR_EN	3V3
69	3V3_IN		3V3_OUT		70	GND		GND
71	VIN_5V0		VIN_5V0		72	GND		GND
73	VIN_5V0		VIN_5V0		74	GND		GND
75	VIN_5V0		VIN_5V0		76	GND		GND
77	VIN_5V0		VIN_5V0		78	GND		GND
79	VIN_5V0		VIN_5V0		80	GND		GND

mikroBUS

HBP 2.4	RZG2L 1.1

HBP 2.4	RZG2L 1.1
MIKROBUS (J8-2)	RZ_SSI0_RXD
MIKROBUS (J8-3)	RZ_RSPI1_SSL
MIKROBUS (J8-4)	RZ_RSPI1_CK
MIKROBUS (J8-5)	RZ_RSPI1_MISO
MIKROBUS (J8-6)	RZ_RSPI1_MOSI
MIKROBUS (J10-1)	RZ_SCIF1_CTS
MIKROBUS (J10-2)	RZ_SCIF1_RTS
MIKROBUS (J10-3)	RZ_SCIF1_RXD
MIKROBUS (J10-4)	RZ_SCIF1_TXD
MIKROBUS (J10-5)	RZ_RIIC0_SCL
MIKROBUS (J10-6)	RZ_RIIC0_SDA

LCD (Parallel Video Output) Signals allocation

LCD	B-to-B connector

LCD	B-to-B connector
DISP_DATA0	J5001-44
DISP_DATA1	J9-52
DISP_DATA2	J9-54
DISP_DATA3	J9-56
DISP_DATA4	J9-58
DISP_DATA5	J5001-43
DISP_DATA6	J5001-45
DISP_DATA7	J9-57
DISP_DATA8	J9-55
DISP_DATA9	J7-43
DISP_DATA10	J7-45
DISP_DATA11	J9-61
DISP_DATA12	J9-59
DISP_DATA13	J7-47
DISP_DATA14	J7-49
DISP_DATA15	J5001-24
DISP_DATA16	J5001-26
DISP_DATA17	J7-14
DISP_DATA18	J7-16
DISP_DATA19	J7-59
DISP_DATA20	J7-56
DISP_DATA21	J7-18
DISP_DATA22	J7-20
DISP_DATA23	J7-22
DISP_HSYNC	J7-30
DISP_VSYNC	J7-32
DISP_DE	J7-34
DISP_CLK	J7-24

Power & Reset

The RZG2L/V2L SOM power source is a single 5V source. It uses Renesas’s PMIC to source all the SOM's power rails. The following figure describes the power architecture.

The power architecture's main features are:

Single 5V power source.
Renesas’s RAA215300 sources the RZG2L/V2L power rails.
3.3V output up to 0.6A (Need to calculate system and SOM power).
Power up sequence is supported by the PMIC configuration.

POWER CONSUMPTION

RZ/G2L Power Table

Mode	Voltage	Current	Power

Mode	Voltage	Current	Power
Idle, Linux up	5V	240mA	1.2W
Linux up, wifi connected to 2.4GHz and sending packet by iperf3	5V	400mA	2W
Linux up, wifi connected to 5GHz and sending packet by iperf3	5V	430mA	2.15W
Linux up, scanning for bluetooth device	5V	250mA	1.25W
Linux up, GPU stress by glmark2	5V	460mA	2.3W
Linux up, CPU stress to maximum	5V	400mA	2W
All utilities are active in the same time (Wifi, GPU stress, CPU stress, Bluetooth)	5V	670mA	3.35W

RZ/V2L Power Table

Mode	Voltage	Current	Power

Mode	Voltage	Current	Power
Idle, Linux up	5V	240mA	1.2W
Linux up, wifi connected to 2.4GHz and sending packet by iperf3	5V	384mA	1.94W
Linux up, wifi connected to 5GHz and sending packet by iperf3	5V	427mA	2.135W
Linux up, scanning for bluetooth device	5V	255mA	1.275W
Linux up, GPU stress by glmark2	5V	480mA	2.4W
Linux up, CPU stress to maximum	5V	384mA	1.92W
Linux up, AI tested with web camera	5V	864mA	4.32W
All utilities are active in the same time (Wifi, GPU stress, CPU stress, Bluetooth)	5V	528mA	2.64W

RESET

The PMIC generates the POR. A reset signal (PMIC_CRST_IN#) from the carrier board can generate a POR.

The PMIC supports a Power ON/OFF* signal to disable/enable all power signals besides RTC.

The PMIC supports an RTC that can be powered by a battery (J7-63).

RZG2L/V2L INTEGRATION MANUAL

POWER UP SEQUENCE

A single 5V input sources the RZG2L/V2L. The PMIC supports all power sequences.

When using the SOM 3.3V output there is no need to consider its power sequence. If an external power source is used for the 3.3V, it must be powered according to the power sequence rules. (See RZG2L/V2L datasheet for details)

BOOTING OPTIONS

Strap pins Booting

The RZG2L/V2L boost from different NVM or serial interfaces according to external resistors setting. The boot configuration is set by the three configuration signals (MD0, MD1, and MD2) and a selection signal (SD0_DEV_SEL) that select between eMMC and uSD (Mux on SOM). Below is a table describing the configuration modes.

MD2 J5001-41	MD1 J5001-5	MD0 J5001-3	SD0_DEV_SEL J9-64	MODE

MD2 J5001-41	MD1 J5001-5	MD0 J5001-3	SD0_DEV_SEL J9-64	MODE
0	0	0	0	uSD (Start up 3.3V)
0	0	1	1	eMMC (1.8V)
0	1	1	N/A	SPI Single/Quad/Octal (1.8V)
1	0	1	N/A	SCIF Download

I2C INTERFACES

The RZG2L/V2L uses I2C2 (PMIC) interfaces for its internal configurations.

GPIO INTERFACES

The RZG2L/V2L SOM uses some GPIO signals for its internal controls. The following table describes the GPIO allocation.

Signal	I/O	Description	Remarks

Signal	I/O	Description	Remarks
ENET_nINT	P27_0	Ethernet interrupt	Active Low
ENET1_nINT	P42_4	Ethernet 1 interrupt	Active Low
WL_REG_ON	P23_1	Enable the WLAN	Active High
BT_REG_ON	P23_0	Enable the BT	Active High

Mechanical Description

Following is a diagram of the TOP VIEW of the RZG2L/V2L.

Documentation

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