Phytec phyCORE-STM32MP13 Series Hardware Manual

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Hardware Manual - phyCORE-STM32MP13x/

phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0)

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Page 1 Hardware Manual - phyCORE-STM32MP13x/ phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) A product of PHYTEC Technology Holding Company...
Page 2 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) Document Title Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) Article Number L-1059e.A0 Release Date 19.10.2023 SOM Prod. No. PCL-076 SOM PCB No. PL1602.0 SBC Prod. No.: PB-02030-xxx CB PCB No.: 1472.x Edition: October 2023 © PHYTEC Messtecknik GmbH...
Page 4: Ordering Information
Production-ready Board Support Packages (BSPs) and Design Services for our hardware will further reduce your development time and risk and allow you to focus on your product expertise. Take advantage of Phytec products to shorten time-to-market, reduce development costs, and avoid substantial design issues and risks. With this new innovative full-system solution, you will be able to bring your new ideas to market in the most timely and cost- efficient manner.
Page 5 Populated on the SOM / SBC With the purchase of a PHYTEC SOM / SBC you will, in addition to our hardware and software possibilities, receive free obsolescence maintenance service for the hardware we provide. Our PCM (Product Change Management) team of developers is continuously processing all incoming PCNs (Product Change Notifications) from vendors and distributors concerning parts that are used in our products.
Page 6 1.5 PHYTEC Documentation PHYTEC will provide a variety of hardware and software documentation for all of our products. This includes any or all of the following: •...
Page 7 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) On top of these standard manuals and guides, PHYTEC will also provide Product Change Notifications, Application Notes, and Technical Notes. These will be done on a case-by-case basis. Most of the documentation can be found on the applicable download page of our products.
Page 8: Conventions, Abbreviations, And Acronyms
Text in blue indicates a hyperlink within, or external to the document. Click these links to quickly jump to the applicable URL, part, chapter, table, or figure. References made to the phyCORE-Connector always refer to the high-density Samtec connector on the undersides of the phyCORE‑STM32MP13x System on Module. © PHYTEC Messtecknik GmbH...
Page 9 Differential line pairs 100 Ohm Ethernet level input ETH_I ETHERNET Output Differential line pairs 100 Ohm Ethernet level output ETH_O ETHERNET IO Differential line pairs 100 Ohm Ethernet level ETH_I/O bidirectional input/output PCIe Input Differential line pairs 100 Ohm PCIe level input PCIe_I © PHYTEC Messtecknik GmbH...
Page 10 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) PCIe Output Differential line pairs 100 Ohm PCIe level output PCIe_O MIPI CSI‑2 Input Differential line pairs 100 Ohm MIPI CSI‑2 level input CSI‑2_I © PHYTEC Messtecknik GmbH...
Page 11: Abbreviations And Acronyms
Solder jumpers; these types of jumpers require solder equipment to remove and place Solderless jumpers; these types of jumpers can be removed and placed by hand with no special tools Printed circuit board PHYTEC Display Interface; defined to connect PHYTEC display adapter boards or custom adapters PHYTEC Extension Board PMIC...
Page 12 User button Sx (e.g. S1, S2, etc.) used in reference to the available user buttons, or DIP-Switches on the carrier board Sx_y Switch y of DIP-Switch Sx; used in reference to the DIP-Switch on the carrier board © PHYTEC Messtecknik GmbH...
Page 13 The phyCORE‑STM32MP13x belongs to Phytec’s phyCORE System on Module family. The phyCORE SOMs represent the continuous development of the PHYTEC System on Module technology. Like its mini-, micro-, and nanoMODUL predecessors, the phyCORE boards integrate all core elements of a microcontroller system on a subminiature board and are designed in a manner that ensures their easy expansion and embedding in peripheral hardware developments.
Page 14 (Product Temperature Grades) The maximum memory size listed is as of the printing of this manual. Please contact PHYTEC for more information about additional, or new module configurations available. Almost every controller port that connects directly to the phyCORE‑Connector may be used as GPIO by using the STM32MP13x's pin muxing options.
Page 15: Block Diagram
Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) 3.2 Block Diagram FIGURE 1: Block Diagram of the phyCORE‑STM32MP13x  Note The specified direction indicated refers to the standard phyCORE use of the pin. © PHYTEC Messtecknik GmbH...
Page 16 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) 3.3 phyCORE-STM32MP13x Component Placement FIGURE 2: phyCORE‑STM32MP13x Component Placement (top view) © PHYTEC Messtecknik GmbH...
Page 17 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) FIGURE 3: phyCORE‑STM32MP13x Component Placement (bottom view) © PHYTEC Messtecknik GmbH...
Page 18 GND pins. In addition, proper implementation of the phyCORE‑STM32MP13x module into a target application also requires connecting all GND pins. Please refer to Power for more information. © PHYTEC Messtecknik GmbH...
Page 19: Pin Description
It also provides the appropriate voltage domain, signal type (ST), and a functional grouping of the signals. The signal type includes also information about the signal direction . A description of the signal types can be found in Types of Signals. © PHYTEC Messtecknik GmbH...
Page 20 SOM is used (e.g. VCC3V3), there is no need to take care of unintended current flow into the SOM, since the voltages of the Peripherals and the SOM will be switched simultaneously. © PHYTEC Messtecknik GmbH...
Page 21 BSP to support all features of the carrier board. If so, information on the differences from the pinout given in the following tables can be found in the carrier board's documentation. © PHYTEC Messtecknik GmbH...
Page 22 ETH1 data A-/transmit- PHY U9 X_ENET1_RX+ signal from onboard ETH_I VDD_3V3 ETH1 data B+/receive+ PHY U9 X_ENET1_RX- signal from onboard ETH_I VDD_3V3 ETH1 data B-/receive- PHY U9 X_ETH1_LED1 signal from onboard VDD_3V3 ETH1 SPEED /LED activity PHY U9 © PHYTEC Messtecknik GmbH...
Page 23 VDD_3V3 LCD data blue4 LTDC_B5 VDD_3V3 LCD data blue5 LTDC_B6 VDD_3V3 LCD data blue6 LTDC_B7 VDD_3V3 LCD data blue7 PH13 LTDC_G2 VDD_3V3 LCD data green2 ( PI4=Input BOOT0 and BOOT0 on module pin47) jumper Segin configuration © PHYTEC Messtecknik GmbH...
Page 24 VDD_3V3 LCD data red7 PI6=Input for Segin VDD_3V3 boot configuration input connected to pin39 for PI6 (BOOT2) boot configuration BOOT2 PI5=Input for Segin VDD_3V3 boot configuration input PI5 (BOOT1) connected to pin40 for boot configuration BOOT1 © PHYTEC Messtecknik GmbH...
Page 25 ETH2 RMII receive data 0 ETH2_RXD1 VDD_3V3 ETH2 RMII receive data 1 PF11 ETH2_RX_ER VDD_3V3 ETH2 RMII receive error PA12 ETH2_CRS_DV VDD_3V3 ETH2 RMII receive enable I2C5_SCL VDD_3V3 I2C5 clock I2C5_SDA VDD_3V3 I2C5 data Ground 0 V © PHYTEC Messtecknik GmbH...
Page 26 Pin on module PA4=SAI1_SCK_B SAI1 jumper Segin configuration transmit bit clock not connected Pin on module jumper Segin configuration GPIO VDD_3V GPIO PA11 PA11 GPIO VDD_3V GPIO PF8 PE11 USART2_CTS VDD_3V USART2 serial clear to send input © PHYTEC Messtecknik GmbH...
Page 27 SAI1_FS_B pinX167) sync on module jumper Segin configuration PF15 DEBUG_JTMS-SWDIO (no BSP VDD_3V JTAG test mode select (JTAG_TMS) config def. GPIO input) ( PF13 = input SAI1_MCLK_B pinX168) and SAI1 master clock on module jumper Segin configuration © PHYTEC Messtecknik GmbH...
Page 28 VDD_3V3 VDD_3V3 PWR_I 3.3 V 3.3 V primary voltage supply input VDD_3V3 VDD_3V3 PWR_I 3.3 V 3.3 V primary voltage supply input VDD_3V3 VDD_3V3 PWR_I 3.3 V 3.3 V primary voltage supply input VDD_3V3 VDD_3V3 PWR_I 3.3 V 3.3 V primary voltage supply input © PHYTEC Messtecknik GmbH...
Page 29 VDD_3V3 PWR_LP Pad is low when the X_PWR_LP system enters Low Power mode. GPIO VDD_3V3 PB0 GPIO GPIO VDD_3V3 PG15 GPIO PG15 UART4_RX ( std. Linux VDD_3V3 UART4 serial data receive Console) ( std. Linux Console) © PHYTEC Messtecknik GmbH...
Page 30 DCMIPP data 1 PG10 DCMIPP_D2 VDD_3V3 DCMIPP data 2 DCMIPP_D3 VDD_3V3 DCMIPP data 3 PD11 DCMIPP_D4 VDD_3V3 DCMIPP data 4 DCMIPP_D5 VDD_3V3 DCMIPP data 5 DCMIPP_D6 VDD_3V3 DCMIPP data 6 PE14 DCMIPP_D7 VDD_3V3 DCMIPP data 7 © PHYTEC Messtecknik GmbH...
Page 31 Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V PC14-OSC32_IN analog VBAT RTC XTALI ( do not use ) PC15- analog VBAT RTC XTALO OSC32_OUT ( do not use ) © PHYTEC Messtecknik GmbH...
Page 32 Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V Ground 0 V X160 VDD_3V3 PF9 GPIO X161 VDD_3V3 PE1 GPIO X162 PE12 VDD_3V3 PE12 GPIO X163 VDD_3V3 PH7 GPIO © PHYTEC Messtecknik GmbH...
Page 33 X175 Port used on PCL-076 VDD_3V3 SDMMC2_D4 module eMMC X176 Port used on PCL-076 VDD_3V3 SDMMC2_D5 module eMMC X177 Port used on PCL-076 VDD_3V3 SDMMC2_D6 module eMMC X178 used on PCL-076 VDD_3V3 SDMMC2_D7 module eMMC © PHYTEC Messtecknik GmbH...
Page 34 VDD_3V3 ETH1_CRS_DV module Ethert-PHY X190 Port used on PCL-076 ETH1_MDINT module Ethert-PHY VREFP ( 1.62 < VDDA) reference (X200) voltage input refer to jumper U8_/WP VDD_3V3 EEPROM Write (TP9) Protetect pin EEPROM Write Protection Control (TP9) © PHYTEC Messtecknik GmbH...
Page 35 SAI is connected to JTAG pins ( Segin Variant jumper J1-J22 PCL-076-xxxxxx1I) Some functions do not exist or differ on STM32MP13x compared to PCL-063. These pins are connected with freeSTM32MP13x Port pins and are marked with © PHYTEC Messtecknik GmbH...
Page 36 Follow the instructions carefully for whatever method of removal is used.  Warning If any modifications to the module are performed, regardless of their nature, the manufacturer's guarantee is null and void. © PHYTEC Messtecknik GmbH...
Page 37 Please pay special attention to the “TYPE” column to ensure you are using the correct type of jumper (0 Ohms, 10k Ohms, etc…). The jumpers are 0402 packages with a 1/8 W or better power rating. The jumpers (J = solder jumper) have the following functions: © PHYTEC Messtecknik GmbH...
Page 38 X_SAI1_SCK_B/PA4 (J4 open) to pin79 X_JTAG_TDI/ 0 Ω (0402) J7=2+3 pin68 X_PWM_TIM2_CH3/PB10 to pin79 X_JTAG_TDI/ J8=1+2 pinX166 X_SAI1_SD_A/PA5 to pin80 X_JTAG_TCK/PF14 0 Ω (0402) J8=2+3 pin76 X_PWM_TIM4_CH2/PD13 to pin80 X_JTAG_TCK/ PF14 J9=close pin103 X_USART1_RX/PB0 pin to pin112 X_SPI1_MISO/ 0 Ω (0402) © PHYTEC Messtecknik GmbH...
Page 39 (0402) J21=clos pin46 X_I2C4_SCL/PE15 to pin28 X_LCD_B5/PE0 0 Ω (0402) J22=clos pin47 X_PI4/BOOT0 to pin31 X_LCD_G2/PH13 1 kΩ (0402) J23=1+2 X_PWR_ON_RST connected to Enable pin U2 0 Ω VDD_DDR3_1V35 regulator ( do not change ) (0402) © PHYTEC Messtecknik GmbH...
Page 40 C memory address 0x52; ID page address 0x5A trol E0 = 0, E1 = 0, E2= 0, => 0x0 / 0x1 (W/R) →I C memory address 0x50; ID page address 0x58 default open ( do not use ) 0 Ω (0402) © PHYTEC Messtecknik GmbH...
Page 41 For maximum EMI performance, all GND pins should be connected to a solid ground plane. 6.2 Voltage Regulator (U2/U3/U4) The phyCORE-STM32MP13x provides 3 x onboard output step-down DC-to-DC converter at positions U2, U3, and U4 to generate the voltages required by the microcontroller and the onboard components. © PHYTEC Messtecknik GmbH...
Page 42: Power Domains
To back up the STM32MP13x's low power domain (VBAT) and its RTC, a secondary voltage source of 1.6 V to 3.6 V can be attached to the phyCORE‑STM32MP13x at pin 94 of X1. VBAT is supplied by VDD_3V3 over diode D1 to if no © PHYTEC Messtecknik GmbH...
Page 43 If a backup supply is connected to pin 94 of X1 diode D3 ensures that only STM32MP13x's VBAT is supplied when the primary system power (VDD_3V3) is removed.  Note If a non-rechargeable source is used a diode should be placed in the VBATpath on the carrier board! © PHYTEC Messtecknik GmbH...
Page 44 VDD_3V3 input voltage and reacts to other reset triggers, e.g. of an external button, too. The reset delay time is typ. 200 ms. The reset output signal X_nRESET_OUT is brought out to allow resetting devices on the carrier board. © PHYTEC Messtecknik GmbH...
Page 45: System Boot Configuration
The BOOT0/2 lines have 100kΩ pull‑up and BOOT1 line 100 kΩ pull-down resistors populated on the module. Differ from PCL-063 specific pin function The boot mode configuration resistors must be placed on the carrier board. See Warning © PHYTEC Messtecknik GmbH...
Page 46 BOOT[2:0]. Make sure that the boot mode inputs X_PI6/ BOOT2 (X1 pin 44), X_PI5/BOOT1 (X1 pin 45), and X_PI4/BOOT0 (X1 pin 47) are not driven by any device on the carrier board during reset. This is to avoid accidental changes to the boot configuration. © PHYTEC Messtecknik GmbH...
Page 48: System Memory
I²C-EEPROM: 4 k (up to 32kB) The following sections detail each memory type used on the phyCORE‑STM32MP13x. The maximum memory size listed is as of the printing of this manual. Please contact PHYTEC for more information about additional, or new module configurations available.
Page 49 Connector Pads on the bottom side. In this case, a bootable memory device must be designed on the baseboard to be able to boot The table below shows the location of the SDMMC2 interface signals on phyCORE-Connector Pads on the bottom side. © PHYTEC Messtecknik GmbH...
Page 50 SD/SDIO/eMMC card data line 5 X177 SD2_D6/PC6 3.3 V SD/SDIO/eMMC card data line 6 X178 SD2_D7/PC7 3.3 V SD/SDIO/eMMC card data line 7 X179 SD2_CMD/PG6 3.3 V SD/SDIO/eMMC card bidirectional command/ response signal X180 SD2_CLK/PE3 3.3 V SD/SDIO/eMMC card clock © PHYTEC Messtecknik GmbH...
Page 51: Serial Interfaces
TABLE 14: Location of the SD / MM Card Interface Signals Pin # Signal Voltage Domain Description PC12 SDMMC1_CK VDD_3V3 SDMMC1 clock SDMMC1_CMD VDD_3V3 SDMMC1 command SDMMC1_D0 VDD_3V3 SDMMC1 data 0 SDMMC1_D1 VDD_3V3 SDMMC1 data 1 © PHYTEC Messtecknik GmbH...
Page 52 UART5 erial data transmit not predefined as uart in std. BSP X_UART7_RX/PE10 VDD_3V3 UART5 serial data receive not predefined as uart in std. BSP X_UART7_TX/PH2 VDD_3V3 UART5 erial data transmit not predefined as uart in std. BSP © PHYTEC Messtecknik GmbH...
Page 53: Ethernet Interface
With an Ethernet PHY mounted at U9, the phyCORE‑STM32MP13x has been designed for use in 10Base-T and 100Base-T networks. The 10/100Base-T interface with its LED signals extends to the phyCORE‑Connector X1. TABLE 17: Location of the Ethernet PHY Signals Pin # Signal Voltage Domain Description X_ENET1_TX+ ETH_O VDD_3V3 ETH1 data A+/transmit+ © PHYTEC Messtecknik GmbH...
Page 54 (bottom side) X181 ENET1_MDIO/ VDD_3V3 ENET1 management data I/O (MDIO) X182 ENET1_MDC/ VDD_3V3 ENET1 management data clock (MDC) X183 ENET1_TX_D0/ VDD_3V3 ENET1 RMII transmit data 0 PG13 X184 ENET1_TX_D1/ VDD_3V3 ENET1 RMII transmit data 1 PG14 © PHYTEC Messtecknik GmbH...
Page 55 MAC address. In order to guarantee that the MAC address is unique, all addresses are managed in a central location. Phytec has acquired a pool of MAC addresses. The MAC address of the phyCORE‑STM32MP13x is located on the barcode sticker attached to the module. This number is a 12-digit HEX value.
Page 56: Spi Interface
C) interface is a two-wire, bidirectional serial bus that provides a simple and efficient method for data exchange among devices. The STM32MP13x contains up to eight identical and independent Multimaster fast-mode I C modules. The interface of the first module (I2C5) is available on the phyCORE-Connector. © PHYTEC Messtecknik GmbH...
Page 57 If too many devices or signal length increases very much, use an I²C buffer to extend the I²C bus. The following table lists the I C port 1 on the phyCORE-Connector. © PHYTEC Messtecknik GmbH...
Page 58: Audio Interfaces
The CAN interface of the phyCORE‑STM32MP13x is connected to the second CANFD module (FDCAN2) of the STM32MP13x which is a full implementation of the CAN protocol specification version 2.0B and CAN FD protocol specification version 1.0. The following table shows the position of the signals on the phyCORE‑Connector. © PHYTEC Messtecknik GmbH...
Page 59 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) TABLE 23: CAN Interface Signal Location Pin # Signal Voltage Domain Description X_GPIO/PA14 VDD_3V3 PA14 (CAN enable) X_FDCAN2_RX/PG3 VDD_3V3 FLEXCAN 1 receive X_FDCAN2_TX/PG1 VDD_3V3 FLEXCAN 1 transmit © PHYTEC Messtecknik GmbH...
Page 60: General Purpose I/Os
PD12 VDD_3V3 VDD_3V3 PG15 VDD_3V3 VDD_3V3 Besides these pins, most of the STM32MP13x signals connected directly to the module connector can be configured to act as GPIO, due to the multiplexing functionality of most controller pins. © PHYTEC Messtecknik GmbH...
Page 61 The phyCORE‑STM32MP13x provides one green user LED (D4) on board. It can be controlled by setting PA13 to the desired output level. A low-level turns the LED on, a high-level off. PA13 is also available on phyCORE‑Connector pin FIGURE 7: User LED Location (top view) © PHYTEC Messtecknik GmbH...
Page 62: Debug Interface
TABLE 25: Debug Interface Signal Location at phyCORE‑Connector X1 Pin # Signal Voltage Domain Description X_JTAG_TMS/PF15 VDD_3V3 JTAG TMS X_JTAG_TDO/PH5 VDD_3V3 JTAG TDO X_JTAG_TCK/PF14 VDD_3V3 JTAG clock input X_JTAG_NJTRST VDD_3V3 JTAG reset input (low active) X_JTAG_TDI/PH4 VDD_3V3 JTAG TDI © PHYTEC Messtecknik GmbH...
Page 63: Parallel Display Interface
LCD data blue 7 X_LCD_G2/PH13 VDD_3V3 LCD data green 2 Ground 0 V X_LCD_G3/PF3 VDD_3V3 LCD data green 3 X_LCD_G4/PD5 VDD_3V3 LCD data green 4 X_LCD_G5/PG0 VDD_3V3 LCD data green 5 X_LCD_G6/PH11 VDD_3V3 LCD data green 6 © PHYTEC Messtecknik GmbH...
Page 64 BSP. For 24-bit support, new pin muxing must be done. 14.2 Supplementary Signals TABLE 27: Supplementary Signals to Support the Display Connectivity Pin # Signal Voltage Domain Description X_PWM_TIM8_CH3/PE5 VDD_3V3 PWM out TIM4_CH2 output (e.g. to control the brightness) © PHYTEC Messtecknik GmbH...
Page 65 The phyCORE-STM32MP13x SOM offers one interface ( DCMIPP) to connect digital cameras. The signals of the parallel Camera Interface DCMIPP are available together with an I C interface at the phyCORE‑Connector to allow for camera connectivity according to PHYTEC's phyCAM‑S+, or phyCAM‑P standard. Please refer to Utilizing the Camera Interfaces on a Carrier Board for more information on how to use the camera interfaces on a carrier board with different interface options.
Page 66 Using the phyCORE's camera interface, together with an I²C bus facilitates easy implementation of a CMOS camera interface, e.g. a phyCAM-P or a phyCAM-S+ interface, on a custom carrier board More information on the PHYTEC camera interface standards phyCAM‑P and phyCAM-S+ and how to implement them on a custom carrier board can be found in phyCAM-P / phyCAM-S Embedded Camera Modules.
Page 67: Tamper Detection
Please refer to the STM32MP13x Reference Manual for more muxing options about this interface. TABLE 29: Tamper Detection Signal Location Pin # Signal Voltage Domain Description X_GPIO/PA6 Tamper detection pin (TAMP_IN2) TAMP_IN2 (PA6) is not predefined as TAMP_IN2 std. © PHYTEC Messtecknik GmbH...
Page 68 Please refer to the STM32MP13x Reference Manual for more muxing options about this interface. TABLE 30: ADC Signal Location Pin # Signal Voltage Domain Description X_GPIO/PF12 ADC input ADC1_IN3 (PF12) (ADC1_IN3) not predefined as ADC1_IN3 std. © PHYTEC Messtecknik GmbH...
Page 69: Technical Specifications
(phyCORE®-STM32MP13x Product Page). Additional specifications: TABLE 31: Technical Specifications Dimensions: 36 mm x 36 mm Weight: [11] approx. 6.2 g Storage temperature: -40 °C to +125 °C Operating temperature: refer to Product Temperature Grades Humidity: 95 % r.F. not condensed © PHYTEC Messtecknik GmbH...
Page 70 Heat resistance of the heat dissipation paths within the system along with the considered usage of a heat spreader or a heat sink to optimize heat dissipation TABLE 32: Product Temperature Grades Product Controller Temp Range (Junction Temp) RAM (Case Others Temp. Temp) (Ambient) Grade © PHYTEC Messtecknik GmbH...
Page 71 1. FIGURE 9: Reference Points (bottom view)  Note To facilitate the integration of the phyCORE‑STM32MP13x into your design, the footprint of the phyCORE‑STM32MP13x is available for download (Integrating the phyCORE-STM32MP13x). © PHYTEC Messtecknik GmbH...
Page 72 Alternatively, a hot air gun can be used to heat and loosen the bonds.  Warning If any modifications to the module are performed, regardless of their nature, the manufacturer's guarantee is voided. © PHYTEC Messtecknik GmbH...
Page 74: Hardware Overview
The phyCORE-STM32MP13x (PCL-076) is a connector-less, BGA-style System On Module (SOM) in a direct solder form factor. Unlike traditional Phytec SOM products that support high-density connectors, the PCL-076 SOM is directly soldered down to the phyBOARD‑Segin STM32MP13x using Half-Hole Technology. This solution offers an ultra-low-cost Single Board Computer for the STM32MP13x processor while maintaining most of the advantages of the SOM concept.
Page 75 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) 20.1.2 Block Diagram FIGURE 10: Block Diagram of the phyBOARD‑Segin STM32MP13x © PHYTEC Messtecknik GmbH...
Page 76 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) 20.1.3 View of the phyBOARD-Segin STM32MP13x FIGURE 11: View of the phyBOARD‑Segin STM32MP13x (top) © PHYTEC Messtecknik GmbH...
Page 77 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) FIGURE 12: View of the phyBOARD‑Segin STM32MP13x (bottom) © PHYTEC Messtecknik GmbH...
Page 78 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) 20.2 Accessing the phyBOARD-Segin STM32MP13x Features PHYTEC phyBOARD‑Segin STM32MP13x is fully equipped with all mechanical and electrical components necessary for a speedy and secure start-up. 20.3 Overview of the phyBOARD-Segin STM32MP13x Peripherals The phyBOARD‑Segin STM32MP13x is depicted in View of the phyBOARD‑Segin STM32MP13x...
Page 79 3.3 V voltage generation on the phyBOARD Power Supply LED D8 Green Indicates the presence of VBUS at the USB host interface (X7) USB Connectivity (X7 and X8) Green Indicates the presence of VBUS at the USB OTG interface (X8) © PHYTEC Messtecknik GmbH...
Page 80 STM32MP13x (top) shows the location of jumpers JP1 and JP5, while the location of jumpers JP2 and JP7 are shown below. FIGURE 13: Jumpers JP2 and JP7 TABLE 36: phyBOARD-Segin i.MX 6UL/ULL Jumper Description Jumper Description Section © PHYTEC Messtecknik GmbH...
Page 81 The required current load capacity for all power supply solutions depends on the specific configuration of the phyCORE mounted on the phyBOARD-Segin STM32MP13x, the particular interfaces enabled while executing software, as well as whether an optional expansion board is connected to the carrier board. © PHYTEC Messtecknik GmbH...
Page 82 • 5 V, 3.3 V, and backlight power supply Pin assignment of the 6–pole WAGO connector: TABLE 38: Pin Assignment of the 6-pole WAGO Connector at X2 Signal Description VCC5V +5 V power supply Ground © PHYTEC Messtecknik GmbH...
Page 83 (max. 3.6 V) to VCC_BACKUP to feed in the backup voltage. Power Supply Connectors(X2), Backup Voltage Connector (X3), and the following table shows the pin assignment of TABLE 39: Pinout of the 2-pole Pin Header X3 Signal Description VCC_BACKUP Backup battery voltage Ground © PHYTEC Messtecknik GmbH...
Page 84 (DTE) and allows for a 5-wire connection, including the signals RTS and CTS for hardware flow control. The following table shows the signal mapping of the RS-232 and RS-485 level signals at connector X5. FIGURE 16: RS-232 or RS‑485 Interface Connector X5 © PHYTEC Messtecknik GmbH...
Page 85 The standard kit comes with an RS-232 transceiver installed. If you need an RS-485 interface at X5 instead, please contact our sales team. 20.4.3 Ethernet Connectivity (X10 and X11) The Ethernet interfaces of the phyBOARD-Segin STM32MP13x are accessible at two RJ45 connectors X10 (Ethernet 1) and X11 (Ethernet 2). © PHYTEC Messtecknik GmbH...
Page 86 MAC address. To guarantee that the MAC address is unique, all addresses are managed in a central location. Phytec has acquired a pool of MAC addresses. The MAC address of the phyBOARD‑Segin STM32MP13x is located on the barcode sticker attached to the module.
Page 87 STM32MP13x is populated with an audio codec at U8. The audio codec is connected to the STM32MP13x's SAI interface to support stereo line input and stereo line output at connector X9. In addition to that the phyBOARD- Segin STM32MP13x has one direct mono speaker output (1 W) at Molex connector X28. © PHYTEC Messtecknik GmbH...
Page 88 (X16)). If the audio codec is to be used in normal operation ensure that jumper JP2 is set to 1+2 which connects the audio codec's reset input to X_nRESET_OUT. The location of JP2 is shown in Audio Codec Disable Jumper JP2. © PHYTEC Messtecknik GmbH...
Page 89 Jumper JP5 can be installed to add a 120 Ohm termination resistor across the CAN data lines if needed. FIGURE 21: Components supporting the CAN Interface(X6, JP5) The following table shows the signal mapping of the CAN signals at connector X6. TABLE 45: Pin Assignment of CAN Connector X6 Signal Signal X_CANL X_CANH Shield © PHYTEC Messtecknik GmbH...
Page 90 Insertable jumper JP1 allows toggling between eMMC boot and boot from the SD card and UART/USB device (DFU). In order to boot from the SD card, JP1 must be set to change the boot configuration (Boot Mode (JP1)). © PHYTEC Messtecknik GmbH...
Page 91 X12 ( CAM_DD2 to CAM_DD9 / CAM_DD0 and CAM_DD1 not connected)) (Figure 17). Information on the phyCAM-P standard and the other possibilities can be found in phyCAM-P / phyCAM-S Embedded Camera Modules. FIGURE 23: phyCAM-P Camera Interface on the phyBOARD‑Segin STM32MP13x © PHYTEC Messtecknik GmbH...
Page 92 Signal Level Description phyCORE Signal Name Name (before (after Level Shifter) LevelShifter phyCAM- P VCC_CAM PWR_O 2.8V Power Supply VCC_CAM PWR_O 2.8V Power Supply VSR_VCCC Analog cf. phyCAM Power Voltage Set datasheet CAM_CTRL VCC_CAM refer to J20 © PHYTEC Messtecknik GmbH...
Page 93 Camera Signal 2 PG10 CAM_DD5 X_DCMIPP_D3/ VCC_CAM Camera Signal 3 Ground CAM_DD6 X_DCMIPP_D4/ VCC_CAM Camera Signal 4 PD11 CAM_DD7 X_DCMIPP_D5/ VCC_CAM Camera Signal 5 Ground CAM_DD8 X_DCMIPP_D6/ VCC_CAM Camera Signal 6 CAM_DD9 X_DCMIPP_D7/ VCC_CAM Camera Signal 7 PE14 © PHYTEC Messtecknik GmbH...
Page 94 VCC_CAM_ X_nRESET_OUT Reset out VCC_CAM PWR_O 2.8V Power Supply VCC_CAM PWR_O 2.8V Power Supply 34,4 Connected 20.4.9 Boot Mode (JP1) The phyBOARD-Segin STM32MP13x has two defined boot sequences which can be selected by configuring jumper JP1. © PHYTEC Messtecknik GmbH...
Page 95 The phyBOARD-Segin STM32MP13x is equipped with a user-defined button at S1. Pressing this button will toggle the PD12 signal (pin X1-99) of the phyCORE SOM low.  Note In order to use S1, the internal pull-up of PD12 must be enabled. This is not preset in BSP. © PHYTEC Messtecknik GmbH...
Page 96 PCB. For further information on the A/V connectors see Expansion Connector (X16). Information on the expansion boards available for the A/V connectors can be found in phyBOARD-Wega Expansion Board Application Guide. © PHYTEC Messtecknik GmbH...
Page 97 GPIOs are available at the expansion female connector. For further information on the expansion connector and the pinout see Expansion Connector (X16). Information on the expansion boards available for the expansion connector can be found in phyBOARD-Wega Expansion Board Application Guide. © PHYTEC Messtecknik GmbH...
Page 98 X_LCD_G2/PH13 This Port should always be configured as input or not muxed/used as in standard BSP. Do not use Boot 0-2 Port Pins on Expansion Connector X16! J10=2+3 on Segin J9=2+3 on Segin J7=2+3 on Segin © PHYTEC Messtecknik GmbH...
Page 99 Modul Pin 44 - 49 Signals STM32MP13x - do not use! ) are routed to A/V connector X14 phyCORE-STM32MP13x Modul Pin 44 - 49 Signals are routed as non-predefined function (GPIO) to expansion connector X16 © PHYTEC Messtecknik GmbH...
Page 100 I C devices must be considered. The table below lists the addresses already in use but shows only the default address. TABLE 52: I2C Addresses in Use Board Prod. No. Device Address used (7 MSB) © PHYTEC Messtecknik GmbH...
Page 101 The following table shows the possible configurations of jumpers J13 and J14. TABLE 53: Routing of the USB OTG Interface Signals J13, J14 J13, J14 Description USB2 interface signals (DM, DP) are routed to USB connector X8 USB2 interface available at expansion connector X16 © PHYTEC Messtecknik GmbH...
Page 102 CAM_CTRL1connected to the phyCAM-P bus transceiver CAM_CTRL2 connected to VCC_CAM CAM_CTRL2 connected to GND CAM_CTRL2 connected to the phyCAM-P bus transceiver For more information on possible configurations with the CAM_CTRLx signals, refer to phyCAM-P / phyCAM-S Embedded Camera Modules. © PHYTEC Messtecknik GmbH...
Page 103 A/V connector X15 makes all signals for display connectivity available, while X14 provides signals for audio and touchscreen connectivity, as well as an I C bus and additional control signals. phyBOARD‑Segin STM32MP13x supports only an 18-bit LCD interface on X14. © PHYTEC Messtecknik GmbH...
Page 104 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) TABLE 56: PHYTEC A/V Connector #1 (X14) Signal Name Type Description Ground [17] X_UART5_RX/PB5 [17] X_UART5_TX/PB13 X_LCD_R2 3.3 V LCD data 12 X_LCD_R3 3.3 V LCD data 13 Ground X_LCD_R4 3.3 V LCD data 14 X_LCD_R5 3.3 V...
Page 105 X_LCD_HSYNC 3.3 V LCD horizontal synchronization X_LCD_VSYNC 3.3 V LCD vertical synchronization Ground Ground X_PWM_TIM8_C 3.3 V Pulse width modulation PWM out H3/PE5 TIM4_CH2 output (to control the brightness) [18] VCC_BL Backlight power supply VCC5V 5.0 V 5.0 V power supply © PHYTEC Messtecknik GmbH...
Page 106 VCC_BL comes directly from pin 4 of power connector X2. Because of that, the voltage level depends on the connected power module and the voltage attached and is not specified here. TABLE 57: PHYTEC A/V Connector #2 (X15) Pin #...
Page 107 I2C5 data 21.2.6.1 Parallel LCD Interface A/V connector X14 provides the signals of the parallel LCD display interface with 18-bit and control signals. The locations of the signals are shown in PHYTEC A/V Connector #2 (X15).  Note The standard configuration of the module provides only an LCD display interface with an 18-bit bus width at A/V connector X14.
Page 108 The expansion connector is intended for use with phyBOARD Expansion Boards , and to add specific functions with custom expansion boards. FIGURE 29: Expansion Connector (X16) The pinout of the expansion connector is shown in the following table. © PHYTEC Messtecknik GmbH...
Page 109 Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) TABLE 60: PHYTEC Expansion Connector X16 Signal Name Usage/ Description Pinmux for SEGIN PB-203 VCC3V3 3.3 V 3.3 V power supply VCC5V 5.0 V 5.0 V power supply VCC1V8 1.8 V 1.8 V power supply Ground X_SPI1_NSS/PC2 SPI1_NSS 3.3 V SPI1 chip select ( USART1_RTS...
Page 110 X_SAI1_SD_A/ [20][21] X_USB_DP_EXP DIFF USB OTG data + X_USB_DM_EXP DIFF [20][21] USB OTG data - X_nRESET_OUT 3.3 V Reset Ground X_PI6/BOOT2 PI6_GPIO / 3.3 V Port PI6 connected to X_LCD_R3/ PB12 refer to PCL-076 module PB12_LCD_R3 X_LCD_R3/PB12 jumper J2 © PHYTEC Messtecknik GmbH...
Page 111 1Ghz Only available for use with overdrive 650Mhz CPU A/C Version mode X_GPIO/PE8 GPIO 3.3 V Port PE8 X_UART7_CTS/ GPIO 3.3 V Port PG15 PG15 X_GPIO/PA6 GPIO 3.3 V GPIO / Tamper detection ( tamper not predefined in BSP) © PHYTEC Messtecknik GmbH...
Page 112 FDCAN2 transmit data CAN1_TX_EXP (UART7_CTS optional ) X_UART7_nRTS / FDCAN2_RX 3.3 V FDCAN2 receive data CAN1_RX_EXP (UART7_RTS optional ) X_ENET1_TX_CLK/ GPIO 3.3 V Port PA11 PA11 GPIO 3.3 V Port PF8 X_PF8 Ground X_I2C1_SCL/PD12 GPIO 3.3 V GPIO PD12 © PHYTEC Messtecknik GmbH...
Page 113 This can be used as a power fail signal for the PEB-POW-01 adapter if the resistor R22 is mounted. VCC_BL connects directly to pin 4 of power connector X2. Because of this, the voltage level depends on the connected power module and the voltage attached. Not specified here. © PHYTEC Messtecknik GmbH...
Page 114 (UART7_RX) and 33 (UART7_TX) of expansion connector X16 to enable implementing a serial interface on a custom expansion board. The following table shows the possible configurations. These settings may vary depending on product variants. TABLE 62: Routing of the UART3 Interface Signals J3, J4 J3, J4 Description © PHYTEC Messtecknik GmbH...
Page 115 TABLE 63: Audio Codec Disable Jumper JP2 Mode Selection Description Audio reset signal (JP2 = 1+2) Audio codec normal operation JTAG mode (JP2 = 2+3) Audio codec disabled, JTAG interface can be used 21.2.7.4 I C Connectivity Please refer to Connectivity. © PHYTEC Messtecknik GmbH...
Page 116 D1 red LED of PEB-EVAL-01 is connected to STM32MP13x Port PC13. On modules equipped with 1GHz CPU, this pin is exclusively on the module for controlling 1 GHz overdrive mode. PC13 is not used to control D1 and is only a visual indicator to see if the CPU is 1 GHz mode. © PHYTEC Messtecknik GmbH...
Page 117: Revision History
Hardware Manual - phyCORE-STM32MP13x/phyBOARD-Segin (1602.0/1472.x) (L-1059e.A0) 22 Revision History Date Version # Changes in this manual Preliminary Manual 19.10.2023 L-1059e.A0 Describes the phyCORE‑STM32MP13x/ phyBOARD-Segin SOM Version: 1602.0 PCB Version: 1472.x © PHYTEC Messtecknik GmbH...

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