TUSB8044RGCEVM

User's Guide SLLU261A – April 2017 – Revised February 2019 TUSB8044RGC Evaluation Module TI's TUSB8044RGC evaluation module (EVM) is a functional board design that implements both a USB 3.0 hub and a USB 2.0 hub. The EVM can support both USB SuperSpeed (SS) and USB 2.0 high-speed (HS), full-speed (FS), or low-speed (LS) operation on its USB ports. The EVM enumerates a Billboard device on a virtual downstream port for USB Type-C™ applications with alternate mode support. It has an I2C Master controllable through an HID-compliant device enumerated on a virtual downstream port. This EVM is intended for use in evaluating system compatibility, developing optional EEPROM firmware, and validating interoperability. This EVM also acts as a hardware reference design for any implementation of the TUSB8044. Contents 1 Introduction ................................................................................................................... 2 Hardware Overview.......................................................................................................... 3 Hardware Setup .............................................................................................................. Appendix A TUSB8044RGC REVD EVM Bill of Materials ................................................................... Appendix B TUSB8044RGC REVD EVM Schematics ....................................................................... 2 3 5 7 9 List of Figures ................................................................................. 1 TUSB8044RGC EVM Top Layer Layout 2 TUSB8044RGC REVD EVM Top Layer Layout ......................................................................... 9 2 3 USB Port Connections..................................................................................................... 10 4 Power ........................................................................................................................ 11 List of Tables 1 Switch Definitions ............................................................................................................ 5 2 TUSB8044 QFN Lab EVM Bill Of Materials: Texas Instruments, CCI and ICP ..................................... 7 Trademarks Microsoft, Windows are registered trademarks of Microsoft Corporation. USB Type-C is a trademark of USB Implementer's Forum. All other trademarks are the property of their respective owners. SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated TUSB8044RGC Evaluation Module 1 Introduction 1 www.ti.com Introduction Upon request, layout files for the EVM can be provided to illustrate techniques used to route the differential pairs, use of split power planes, placement of filters and other critical components, and methods used to achieve length matching of critical signals. NOTE: The EVM accommodates various lab test components; actual production implementations can be much smaller. Figure 1 illustrates the TUSB8044RGC EVM top layer layout. Figure 1. TUSB8044RGC EVM Top Layer Layout 2 TUSB8044RGC Evaluation Module SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated Hardware Overview www.ti.com 2 Hardware Overview The TUSB8044RGCEVM board hardware can be divided into the following functional areas: 2.1 TUSB8044RGC The TUSB8044 on the TUSB8044 EVM (U1 on the schematic) operates as a functional interconnect between an upstream connection to a USB host or hub and up to four directly connected downstream devices or hubs. More devices and hubs can be supported if arranged in tiers. The TUSB8044 is capable of supporting operation at USB SuperSpeed (SS), high speed (HS), full speed (FS), or low speed (LS). In general, the speed of the upstream connection of the TUSB8044RGCEVM limits the downstream connections to that speed (SS, HS, and FS), or lower. The TUSB8044 enumerates a Billboard device on a virtual downstream port for USB Type-C applications with alternate mode support. It also has an I2C Master controllable through an HID compliant device enumerated on a virtual downstream port. The TUSB8044 requires a 24-MHz low-ESR crystal, Y1, with a 1-MΩ feedback resistor. The crystal should be in fundamental mode with a load capacitance of 12 to 24 pF and a frequency stability rating of ±100 PPM or better. To ensure a proper startup oscillation condition, TI recommends a maximum crystal equivalent series resistance (ESR) of 50 Ω. The TUSB8044 can also use an oscillator or other clock source. When using an external clock source such as an oscillator, the reference clock should have ±100 PPM (or better) frequency stability and have less than 50-ps absolute peak-to-peak jitter (or less) than 25-ps peak-to-peak jitter after applying the USB 3.0 jitter transfer function. 2.2 USB Port Connectors The TUSB8044 EVM is equipped with five standard 9-pin USB 3.0 port connectors. One of these five connectors, J1, is a Type B connector designed to interface with an upstream USB host or hub. The remaining connectors, J2, J3, J4, and J5, are Type A connectors for connection to downstream devices or hubs. Standard size connectors were used on the EVM design, but USB micro connectors can be used, if desired. The USB ports can be attached through a standard USB cable to any USB 3.0 or legacy USB host, hub, or device. The TUSB8044 will automatically connect to any upstream USB 3.0 host or hub at both SS and HS. Using a legacy USB cable between the TUSB8044 EVM and a USB 3.0 host or hub forces it to HS operation. The same is true if a legacy USB cable is used between the TUSB8044 EVM and a downstream SS-capable device; operation will be limited to USB 2.0 HS. 2.3 USB Port Connector – Power VBUS is received from the upstream host or hub on J1. The TUSB8044 is configured as a self-powered hub, so there is not any significant current draw by the EVM from VBUS. The TUSB8044 does monitor the VBUS input after filtering through a resistor divider network of a 90.9-kΩ, 1% resistor, R2, and a 10-kΩ, 1% resistor, R3. VBUS cannot be directly connected to the TUSB8044 device. A bulk capacitor of at least 1 μF is required on the upstream port VBUS input to comply with the USB specification. The TUSB8044EVM uses a 10-μF capacitor, C35. VBUS, sourced by the 5-V wall power input, J6, is provided to the downstream port connectors. The USB 3.0 specification limits the current consumption of a USB 3.0 device to 900 mA at 5 V. The current limiting parameter of the TPS2001C devices, U7, U8, U9, and U10, is 2 A to avoid any spurious overcurrent events due to bus-powered HDD spin-up power fluctuations or unnecessary limiting during USB charging. A production implementation could place stricter limits on this power consumption. An overcurrent event on any of the downstream port connectors will be reported to the TUSB8044 through the OVERCURxZ inputs. SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated TUSB8044RGC Evaluation Module 3 Hardware Overview 2.4 www.ti.com USB Port Connector – Noise Filtering Each downstream VBUS output has a 150-μF bulk capacitor (C70, C71, C76, C79) as recommended by the TPS2001C data manual (SLVSAU6) to prevent in-rush current events on the downstream devices. In addition, there are ferrite beads and small capacitors on the VBUS lines to reduce noise and address ESD and EMI concerns. The TUSB8044EVM also implements optional isolation using two small noise-filtering capacitors and a 1MΩ resistor between the earth ground of each connector and the digital ground of the EVM; this is not a requirement, but should be used if ground isolation is desired. NOTE: Note that the series capacitors implemented on the SS TX pairs are incorporated to satisfy the USB 3.0 requirement that differential links be AC coupled on the transmit pair. 2.5 Optional Serial EEPROM Each TUSB8044EVM is equipped with an onboard EEPROM or socket placeholder, U2. A small I2C EEPROM can be installed to set the configuration registers as defined in the TUSB8044 data manual (SLLSEW5). In its default setting, the EVM does not have an EEPROM installed and instead uses the configuration inputs to determine any optional settings of the TUSB8044. The EEPROM interface defaults to programmable (not write-protected) so that any installed contents on the EEPROM may be modified to test various settings. If an EEPROM data change is required, the values may be changed using the register access methods outlined in the TUSB8044 data sheet. In addition, a Microsoft® Windows® based EEPROM utility is available upon request. 2.6 Power The TUSB8044 EVM operates from the power provided by a 5-V wall power adapter, J6, not bus power supplied by a USB host. TI recommends to use a wall power adapter that is capable of sourcing 2 to 3 A because the hub must be able to source significant power on its downstream ports (900 mA per port). The TUSB8044 EVM uses a single-channel LDO voltage regulator to drop 5 V to 3.3 V. The TPS7A4533, U4, is a 1.5-A output linear regulator (SLVS720). The 1.1-V core voltage required by the TUSB8044 is sourced by the 3.3-V rail to reduce unnecessary heat dissipation. The TPS74801, U6, is a 1.5-A output single channel LDO linear regulator (SBVS074). Both regulators require few external passive components and are appropriately rated for heat dissipation. 2.7 Hub Configuration The TUSB8044EVM can be configured by setting several inputs to the TUSB8044 that are sampled at power-on reset or using an optional serial EEPROM or SMBUS host. A production implementation without EEPROM or SMBUS could either rely on the default internal pullup or pulldown resistor for each configuration input or override it with an external pullup or pulldown resistor. The settings can be modified using SW1 and SW2 on the EVM. Descriptions of the possible configuration changes are included in Section 3.1. 2.8 Optional Circuitry The TUSB8044 EVM design implements a variety of LEDs, none of which are required by the USB specification. They are provided to make testing and debugging easier. • D1 – indicates that the upstream USB port power is on • D4 – indicates that 3.3 V is being applied to the TUSB8044 EVM • D5 – indicates downstream USB port 1 power is on • D6 – indicates downstream USB port 2 power is on • D7 – indicates downstream USB port 3 power is on • D8 – indicates downstream USB port 4 power is on The switches (SW1, SW2, and SW3) and headers (J7, J8, J9) present on the TUSB8044 EVM are intended only for lab evaluation and are not required for production designs. 4 TUSB8044RGC Evaluation Module SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated Hardware Setup www.ti.com 3 Hardware Setup 3.1 Configuration Switch The TI TUSB8044EVM has a set of switches to facilitate configuration changes. TI does not recommend changing these switch settings without a complete understanding of the result. Configuration inputs are only read by the TUSB8044 during power-on reset, changing the switch settings while the EVM is powered on will have no effect. For additional information, refer to the EVM schematic in Appendix B. The switch definitions are shown in Table 1. Table 1. Switch Definitions Switch Standard SW1_1 Off Definition TEST_TRSTz Switch The TUSB8044 has an internal pulldown on this terminal. If the switch is set to the ON position, the terminal is pulled high and test mode is enabled. This is a production test mode only. SW1_2 Off SMBUSz Switch The TUSB8044 has an internal pullup on this terminal, so I2C interface mode is enabled by default. If the switch is set to the ON position, the terminal is pulled low and SMBUS mode is enabled. SW1_3 Off SCL_SMBCLK Switch The TUSB8044 has an internal pulldown on this terminal, so the serial EEPROM or SMBUS interface is disabled. If the switch is set to the ON position, a pullup resistor is connected to the serial clock terminal to indicate that an I2C EEPROM may be attached (along with a pullup resistor on SDA). SW1_4 Off SDA_SMBDAT Switch The TUSB8044 has an internal pulldown on this terminal, so the serial EEPROM or SMBUS interface is disabled. If the switch is set to the ON position, a pullup resistor is connected to the serial clock terminal to indicate that an I2C EEPROM may be attached (along with a pullup resistor on SCL). SW1_5 Off PWRON1_BATEN1 Switch The TUSB8044 has an internal pulldown on this terminal, so USB battery charging mode on Port 1 is disabled by default. If the switch is set to the ON position, the terminal is pulled high and battery charging is enabled on downstream port 1. SW1_6 Off PWRON2_BATEN2 Switch The TUSB8044 has an internal pulldown on this terminal, so USB battery charging mode on Port 2 is disabled by default. If the switch is set to the ON position, the terminal is pulled high and battery charging is enabled on downstream port 2. SW1_7 Off PWRON3_BATEN3 Switch The TUSB8044 has an internal pulldown on this terminal, so USB battery charging mode on Port 3 is disabled by default. If the switch is set to the ON position, the terminal is pulled high and battery charging is enabled on downstream port 3. SW1_8 Off PWRON4_BATEN4 Switch The TUSB8044 has an internal pulldown on this terminal, so USB battery charging mode on Port 4 is disabled by default. If the switch is set to the ON position, the terminal is pulled high and battery charging is enabled on downstream port 4. SW2_1, SW2_7 Off AUTOENZ_PD/BB_bmConfig1_PD Switch When configured for I2C mode, this pin along with BBbmConfigured0 directly controls the bmConfigurated field in the Billboard Capability descriptor. If SMBus is selected, then bmConfigured[1] field is determined by a register. If SMBus is selected, the sampled value of this pin will set or clear the autoEnz bit in the Battery Charging Support Register. SMBus master can at a later time override the register. If SMBus is selected and stsOutputEn bit is set, this pin will function as a HS_SUSPEND (upstream HS suspend indicator). When enabled, a value of 1 indicates the connection is suspended. SW2_2 Off GANGED_HS_UP/BB_CONNECT Switch When configured for I2C mode, this pin functions as Billboard Enable. When high, the billboard device is enabled and presented to system. When low, the billboard device is disabled. If SMBus is selected, then Billboard Enable is controlled by a register. If SMBus is selected and stsOutputEn bit is set, this pin will function as a HS_UP (upstream HS connection indicator). When enabled, a value of 1 indicates the upstream port is connected to a HS USB-capable port. If SMBus is selected, the value of the pin is sampled at the de-assertion of reset to set the power switch and overcurrent detection mode as follows: 0 = Individual port power control supported. 1 = Ganged port power control supported. SMBus master can at a later time override the register. SW2_3 Off PWRCTL_POL Switch The TUSB8044 has an internal pullup on this terminal, so port power control polarity defaults to active high. If the switch is set to the ON position, the terminal is pulled low and the port power control polarity changes to active low. SW2_4 Off FULLPWRMGMTZ_SS_UP/BB_bmConfig0 Switch When configured for I2C mode, this pin along with BBbmConfigured1 directly controls the bmConfigurated field in the Billboard Capability descriptor. If SMBus is selected, then bmConfigured[0] field is determined by a register. If SMBus is selected and battery charging is enabled on any port, the sampled state of this pin will set or clear the FullAutoEn bit in the Device Configuration Register 3. SMBus master can at a later time override the register. If SMBus is selected and battery charging is disabled, then the value of the pin is sampled at the de-assertion of reset to set the power switch control: SMBus master can override this function at a later time. 0 = Power Switching and over current inputs supported. 1= Power Switch and over current inputs not supported. If SMBus is selected and stsOutputEn bit is set, ths pin will function as an SS_UP (upstream SS connection indicator). When enabled, a value of '1' indicates the upstream port is connected to a SuperSpeed USB capable port. SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated TUSB8044RGC Evaluation Module 5 Hardware Setup www.ti.com Table 1. Switch Definitions (continued) 3.2 Switch Standard SW2_5 Off SCL_SMBCLK PD Switch The TUSB8044 has an internal pulldown on this terminal, so the serial EEPROM or SMBUS interface is disabled. If the switch is set to the ON position, an external pulldown resistor is connected to the serial clock terminal for test purposes. SW2_6 Off SDA_SMBDAT PD Switch The TUSB8044 has an internal pulldown on this terminal, so the serial EEPROM or SMBUS interface is disabled. If the switch is set to the ON position, an external pulldown resistor is connected to the serial clock terminal for test purposes. EVM Installation To 1. 2. 3. 3.3 Definition install the EVM, perform the following steps: Attach a 5-V, 3-A wall power source to J6. Turn on switch SW3, LED D4 should be lit. Attach a USB cable between J3 and a USB host. LEDs D1, D5, D6, D7 and D8 should be lit. Troubleshooting Case 1: Device function or functions are “banged out” in Device Manager. • Make sure that the latest updates are installed for the operating system. • Make sure that the latest drivers are installed for the host controller. Case 2: The EVM does not work at all. • Verify that all switches are in their default state and the EVM is powered on with a 5-V source with adequate current to support any bus-powered devices (3 A+). • If installed, remove the serial EEPROM from the EEPROM socket. The EVM does not require an EEPROM to operate. • Make sure shunts are installed on J7, J8, and J9. • In the case where a 12-V power supply has been attached to the EVM, the fault is non-recoverable. 6 TUSB8044RGC Evaluation Module SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated Appendix A SLLU261A – April 2017 – Revised February 2019 TUSB8044RGC REVD EVM Bill of Materials This appendix contains the TUSB8044RGC REVD EVM BOM. Table 2. TUSB8044 QFN Lab EVM Bill Of Materials: Texas Instruments, CCI and ICP Item Qty Reference Part Manufacturer Part Number Pkg Description 1 1 C5 1uF Murata GRM219R61A105KA01D 805 1µF ±10% 10V Ceramic Capacitor X5R 0805 (2012 Metric) 2 1 C3 1uF Samsung CL05B105KQ5NQNC 402 CAP CER 1UF 6.3V 10% X7R 0402 3 5 C39,C47,C49,C57 ,C59 0.001uF TDK C1005X7R1H102K 402 CAP CER 1000PF 50V X7R 10% 0402 4 9 C6,C9,C12,C15,C 19,C22,C25,C28, C32, 0.001uF TDK C0603X7R1E102K030BA 201 CAP CER 1000PF 25V 10% X7R 0201 5 9 C7,C10,C13,C16, C20,C23,C26,C29 ,C33 0.01uF Yageo CC0201KRX7R7BB103 201 CAP CER 10000PF 16V 10% X7R 0201 6 18 C4,C38,C40,C41, C46,C48,C50,C51 ,C56,C58,C66,C6 9,C72,C75,C77,C 78,C80,C81 0.1uF Yageo CC0402KRX5R6BB104 402 CAP CERAMIC .1UF 10V X5R 0402 7 19 C8,C11,C14,C17, C21,C24,C27,C30 ,C34,C36,C37,C4 2,C43,C44,C45,C 52,C53,C54,C55 0.1uF TDK C0603X5R0J104M 201 CAP CER .10UF 6.3V X5R 0201 8 2 C1,C2 18pF AVX 04025A180JAT2A 402 CAP CERM 18PF 5% 50V NP0 0402 9 9 C18,C31,C35,C61 ,C67,C68,C73,C7 4,C82 10uF Murata Electronics GRM31CR61C106KA88L 1206 CAPACITOR CERM 10UF 16V 10% SMD 10 4 C70,C71,C76,C79 150uF Kemet T495D157K010ATE100 (Tantalum) 7343 CAP TANT 150UF 10V 10% LOESR SMD 11 0 R10,R32,R42,R43 ,R44,R45 NOPOP 12 6 D1,D4,D5,D6,D7, D8 LED Green 0805 Lite On LTST-C171GKT 805 LED GREEN CLEAR THIN 0805 SMD 13 0 D2,D3 LED Green 0805 NOPOP Lite On LTST-C171GKT 805 LED GREEN CLEAR THIN 0805 SMD 14 5 FB1,FB3,FB4,FB5 ,FB6 220 @ 100MHZ Ferrite Bead Murata BLM18PG221SN1D 603 FERRITE CHIP 220 OHM 1400MA 0603 15 2 SW1,SW2 8-POS 50-MIL SMT C&K Components SD08H0SBR 16 1 J1 USB3_TYPEB_C ONNECTOR Amphenol GSB321131HR 9_RA_TH_B CONN RCPT USB 3.0 TYPE B R/A 9PS 17 4 J2,J3,J4,J5 USB3_TYPEA_C ONNECTOR Amphenol GSB311131HR 9_RA_TH_A CONN RCPT USB 3.0 TYPE A R/A 9PS 18 1 J6 2.1mm x 5.5mm DC Power Jack CUI Inc. PJ-202AH 2.1mm x 5.5mm CONN PWR JACK 2.1X5.5MM HIGH CUR 19 6 R1,R15,R17,R18, R19,R20 1M Rohm Semiconductor MCR01MZPJ105 402 RES 1.0M OHM 1/16W 5% 0402 SMD 20 1 R2 90.9K 1% Rohm Semiconductor MCR01MZPF9092 402 RES 90.9K OHM 1/16W 1% 0402 SMD 21 4 R26,R27,R29,R36 10K Rohm Semiconductor MCR01MZPJ103 402 RES 10K OHM 1/16W 5% 0402 SMD 22 1 R3 10K 1% Rohm Semiconductor MCR01MZPF1002 402 RES 10K OHM 1/16W 1% 0402 SMD 23 4 R6,R7,R8,R9 4.7K Rohm Semiconductor MCR01MZPJ472 402 RES 4.7K OHM 1/16W 5% 0402 SMD 402 SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback SWITCH DIP SPST SEALED 8POS SMD TUSB8044RGC REVD EVM Bill of Materials Copyright © 2017–2019, Texas Instruments Incorporated 7 Appendix A www.ti.com Table 2. TUSB8044 QFN Lab EVM Bill Of Materials: Texas Instruments, CCI and ICP (continued) Item Qty Reference Part Manufacturer Part Number Pkg Description 24 15 R4,R5,R11,R12,R 13,R14,R22,R23, R24,R25,R38,R39 ,R46, R47, R48 1K Rohm Semiconductor MCR01MZPJ102 402 RES 1.0K OHM 1/16W 5% 0402 SMD 25 8 R16,R28,R30,R31 ,R35,R37, 330 Rohm Semiconductor MCR01MZPJ331 402 RES 330 OHM 1/16W 5% 0402 SMD 26 1 R33 1.87K Vishay / Dale CRCW04021K87FKED 402 RES 1.87K OHM 1/16W 1% 0402 SMD 27 1 R34 4.99K Vishay / Dale CRCW04024K99FKED 402 RES 4.99K OHM 1/16W 1% 0402 SMD 28 1 R21 9.53K 1% Rohm Semiconductor MCR01MRTF9531 402 RES 9.53K OHM 1/16W 1% 0402 SMD 29 1 U1 TUSB8044 - USB 3.0 Hub Texas Instruments TUSB8044RGC 64QFN 30 1 U2 AT24C04 I2C EEPROM Assmann WSW Components A 08-LC-TR 8DIP CONN IC DIP SOCKET 8POS TIN 31 4 U7,U8,U9,U10 TPS2001C Texas Instruments TPS2001CDGN 8DGN IC PWR SW USB 2.87A 1CH 8MSOP 32 1 U4 TPS7A4533 - 3.3V Voltage Regulator Texas Instruments TPS7A4533KTT DDPAK-5 IC REG LDO 3.3V 1.5A 5-DDPAK 33 1 U6 TPS74801RGW 1.1V Voltage Regulator Texas Instruments TPS74801RGW 20VQFN IC REG LDO ADJ 1.5A 20VQFN 34 1 Y1 ECS-24MHZ Crystal ECS ECS-240-20-30B-TR 5.0mm x 3.2mm CRYSTAL 24.000 MHZ 20PF SMD 35 4 PCB Standoff Keystone Electronics 2203 HEX STANDOFF 4-40 ALUMINUM 1/2" 36 4 Screw Keystone Electronics 9900 MACHINE SCREW PAN PHILLIPS 4-40 37 1 FB2 0 ohm Yageo RC0603JR-070RL 603 38 0 JP6 Conn 2x5 shroud NO POP 3M 2510-6003UB HDR5X2 M 0.1" TH 39 6 J7,J8,J9,J10,J11,J 12 Header 1x2 3M 961102-6404-AR HDR2X1 M 0.1" TH CONN HEADER VERT SGL 2POS GOLD 40 1 J13 Header 3PIN 3M 961102-6404-AR HDR2X1 M 0.1" TH CONN HEADER VERT SGL 2POS GOLD 41 1 SW3 Power Switch L101011MS02Q C&K Components L101011MS02Q SPST 42 0 GND1, GND2 NOPOP 43 1 LB1 sticker 3M 695-WHITE-2"X36YD add text: TUSB8044RGCEVM INT077-001 REV A 44 6 Shunt Shunt 3M 969102-0000-DA Place shunts on: J7,J8,J9,J10,J11,J12 45 1 PCB BOARDS TUSB8044RGCE VM INT077-001 TUSB8044RGCEVM PCBBOARD R40,R41 8 TUSB8044RGC REVD EVM Bill of Materials RES 0.0 OHM 1/10W 0603 SMD SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated Appendix B SLLU261A – April 2017 – Revised February 2019 TUSB8044RGC REVD EVM Schematics Figure 2 through Figure 4 the TUSB8044RGC REVD EVM schematics. BOARD_3P3V R1 1M USB_SSRXN_UP USB_SSRXP_UP USB_SSTXM_UP USB_SSTXP_UP USB_DM_UP USB_DP_UP Y1 VDD33 VDD11 R2 GRSTZ ECS-24MHZ C1 C2 18pF 18pF R21 1 TEST_TRSTZ C3 9.53K R3 10K 0402 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 1uF 2 2 USB_DP_DN1 USB_DM_DN1 USB_SSTXP_DN1 USB_SSTXM_DN1 USB_SSRXP_DN1 USB_SSRXM_DN1 2 2 2 2 USB_DP_DN2 USB_DM_DN2 USB_SSTXP_DN2 USB_SSTXM_DN2 2 2 USB_SSRXP_DN2 USB_SSRXM_DN2 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 USB_DP_DN1 USB_DM_DN1 USB_SSTXP_DN1 USB_SSTXM_DN1 VDD11 USB_SSRXP_DN1 USB_SSRXM_DN1 VDD11 USB_DP_DN2 USB_DM_DN2 USB_SSTXP_DN2 USB_SSTXM_DN2 VDD11 USB_SSRXP_DN2 USB_SSRXM_DN2 VDD33 2 2 2 2 2 2 PPAD 2 USB_VBUS_UP 2 R44 NOPOP R43 NOPOP R42 NOPOP JP6 1 3 5 7 9 JTAG is for lab evaluation only on TUSB8044. This header and NOPOP pullups are not recommended for customers. Header 1x2 90.9K 0402 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 R45 NOPOP TEST_TRSTZ PWRCTL_POL_TDO OVERCUR1Z_TDI OVERCUR2Z_TMS OVERCUR3z_TCK OVERCUR2Z_TMS OVERCUR1Z_TDI AUTOENZ/BB_bmConfig1 OVERCUR2Z_TMS OVERCUR1Z_TDI 3 3 OVERCUR3Z_TCK GANGED_HS_UP/BB_CONNECT PWRCTL_POL_TDO FULLPWRMGMTZ_SS_UP/BB_bmConfig0 SMBUSZ SCL_SMBCLK SDA_SMBDAT 3 PWRON1_BATEN1 PWRON2_BATEN2 PWRON3_BATEN3 PWRON4_BATEN4 2 4 6 8 10 Conn 2x5 shroud 3 3 3 3 65 BOARD_3P3V 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 TUSB8044 2 2 2 2 2 2 USB_VBUS OVRCUR2Z_TMS OVRCUR1Z_TDI AUTOENZ_HS_SUSPEND OVRCUR3Z_TCK OVRCUR4Z GANGED_SMBA2_HS_UP PWRCTL_POL_TDO FULLPWRMGMTZ_SMBA1_SS_UP SMBUSZ_SS_SUSPEND SCL_SMBCLK SDA_SMBDAT PWRON1Z_BATEN1 PWRON2Z_BATEN2 VDD33 PWRON3Z_BATEN3 USB_DP_DN3 USB_DM_DN3 USB_SSTXP_DN3 USB_SSTXM_DN3 VDD11 USB_SSRXP_DN3 USB_SSRXM_DN3 USB_DP_DN4 USB_DM_DN4 USB_SSTXP_DN4 USB_SSTXM_DN4 VDD11 USB_SSRXP_DN4 USB_SSRXM_DN4 VDD11 PWRON4Z_BATEN4 2 2 2 2 USB_R1 VDD33 XI XO NC USB_SSRXM_UP USB_SSRXP_UP VDD11 USB_SSTXM_UP USB_SSTXP_UP USB_DM_UP USB_DP_UP VDD33 VDD11 GRSTN TEST_TRSTz U1 J8 2 2 2 2 2 2 USB_DP_DN3 USB_DM_DN3 USB_SSTXP_DN3 USB_SSTXM_DN3 USB_SSRXP_DN3 USB_SSRXM_DN3 USB_DP_DN4 USB_DM_DN4 USB_SSTXP_DN4 USB_SSTXM_DN4 USB_SSRXP_DN4 USB_SSRXM_DN4 R22 1K 0402 SW1 8-POS 50-MIL SMT TEST_TRSTZ SMBUSZ SCL_SMBCLK SDA_SMBDAT PWRON1_BATEN1 PWRON2_BATEN2 PWRON3_BATEN3 PWRON4_BATEN4 1 2 3 4 5 6 7 8 16 15 14 13 12 11 10 9 R4 1K 0402 R5 1K 0402 R6 4.7K 0402 R7 4.7K 0402 R8 4.7K 0402 R9 4.7K 0402 TEST_PUP SMBUSZ_PD SCL_PUP SDA_PUP BATEN0 BATEN1 BATEN2 BATEN3 R24 1K 0402 BOARD_3P3V Plac e shunts on: J7,J8,J9,J10,J11,J12 BOARD_3P3V R23 1K AUTOENZ/BB_bmConfig1 C4 0.1uF Optional EEPROM Circuitry R10 NOPOP GANGED_HS_UP/BB_CONNECT U2 R11 1K 0402 R12 1K 0402 R13 1K 0402 PWRCTL_POL_TDO A0 A1 A2 GND VCC WP SCLK SDATA 8 7 6 5 2 FULLPWRMGMTZ_SS_UP/BB_bmConfig0 SCL_SMBCLK 1 1 2 3 4 5 6 7 8 GANGED_HS_UP/BB_CONNECT_2 Header 1x2 SDA_SMBDAT SW2 8-POS 50-MIL SMT AUTOENZ/BB_bmConfig1_2 Header 1x2 J11 1 2 FULLPWRMGMTZ_SS_UP/BB_bmConfig0_2 J12 2 D3 Header 1x2 LED-DNI D2 LED-DNI US HS 16 15 14 13 12 11 10 9 R14 1K 0402 J13 3 R48 1K GANGED_PU/BB_CONNECT_PU PWRCTL_POL_PD FULLPWRMGMTZ_PUP/BB_bmConfig0_PU SCL_PD SDA_PD AUTOENZ_PU/BB_bmConfig1_PU US SS AT24C04 2 1 R38 1K AUTOENZ_PD/BB_bmConfig1_PD R46 1K R40 R41 330 - DNI 330 - DNI VDD33 R47 1K R39 1K BOARD_3P3V FB1 J7 1 C6 C5 1uF C7 0.01uF 0.001uF C8 C9 C10 0.1uF 0.001uF 0.01uF C11 0.1uF C12 C13 C14 C15 C16 C17 0.001uF 0.01uF 0.1uF 0.001uF 0.01uF 0.1uF 220 @ 100MHZ VDD11 2 Header 1x2 BOARD_1P1V FB2 J9 1 C19 C20 C21 C22 C23 C24 C25 C26 C27 C28 C29 C30 0.001uF 0.01uF 0.1uF 0.001uF 0.01uF 0.1uF 0.001uF 0.01uF 0.1uF 0.001uF 0.01uF 0.1uF C31 10uF C32 C33 C34 0.001uF 0.01uF 0.1uF GND1 220 @ 100MHZ Header 1x2 1 C18 10uF 2 GND2 1 1 2 3 4 R25 1K J10 1 Copyright © 2017, Texas Instruments Incorporated Figure 2. TUSB8044RGC REVD EVM Top Layer Layout SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback TUSB8044RGC REVD EVM Schematics Copyright © 2017–2019, Texas Instruments Incorporated 9 Appendix B www.ti.com USB_VBUS_UP 1 J1 VBUS DM DP GND SSTXN SSTXP GND SSRXN SSRXP SHIELD0 SHIELD1 1 2 3 4 5 6 7 8 9 10 11 CAP_UP_TXM CAP_UP_TXP C38 0.1uF USB3_TYPEB_CONNECTOR C36 0.1uF 0201 C37 0.1uF 0201 C39 0.001uF USB_DM_UP 1 USB_DP_UP 1 USB_SSTXM_UP 1 USB_SSTXP_UP USB_SSRXN_UP USB_SSRXP_UP 1 1 1 C35 10uF D1 LED Green 0805 R15 1M 0402 R16 330 0402 FB3 FB4 DN4_VBUS C40 0.1uF J2 VBUS DM DP GND SSRXN SSRXP GND SSTXN SSTXP SHIELD0 SHIELD1 1 2 3 4 5 6 7 8 9 10 11 DN4_VBUS DN2_VBUS 3 220 @ 100MHZ J3 VBUS_DS4 USB_DM_DN4 USB_DP_DN4 CAP_DN_TXM4 CAP_DN_TXP4 C42 0.1uF 0201 C44 0.1uF 0201 VBUS DM DP GND SSRXN SSRXP GND SSTXN SSTXP SHIELD0 SHIELD1 1 1 USB_SSRXM_DN4 USB_SSRXP_DN4 USB_SSTXM_DN4 1 1 1 USB_SSTXP_DN4 1 USB3_TYPEA_CONNECTOR VBUS_DS2 1 2 3 4 5 6 7 8 9 10 11 USB_DM_DN2 USB_DP_DN2 CAP_DN_TXM2 CAP_DN_TXP2 C43 0.1uF 0201 C45 0.1uF 0201 C47 0.001uF R17 1M 0402 C48 0.1uF C49 0.001uF 1 1 USB_SSRXM_DN2 USB_SSRXP_DN2 USB_SSTXM_DN2 1 1 1 USB_SSTXP_DN2 1 R18 1M 0402 FB5 FB6 DN1_VBUS C50 0.1uF J4 VBUS DM DP GND SSRXN SSRXP GND SSTXN SSTXP SHIELD0 SHIELD1 3 USB3_TYPEA_CONNECTOR C46 0.1uF 1 2 3 4 5 6 7 8 9 10 11 DN2_VBUS C41 220 @ 100MHZ 0.1uF VBUS_DS1 DN1_VBUS 220 @ 100MHZ C52 0.1uF 0201 C54 0.1uF 0201 C51 0.1uF J5 USB_DM_DN1 USB_DP_DN1 CAP_DN_TXM1 CAP_DN_TXP1 DN3_VBUS 3 1 1 USB_SSRXM_DN1 USB_SSRXP_DN1 USB_SSTXM_DN1 1 1 1 USB_SSTXP_DN1 1 USB3_TYPEA_CONNECTOR VBUS DM DP GND SSRXN SSRXP GND SSTXN SSTXP SHIELD0 SHIELD1 1 2 3 4 5 6 7 8 9 10 11 VBUS_DS3 USB_DM_DN3 USB_DP_DN3 CAP_DN_TXM3 CAP_DN_TXP3 DN3_VBUS 3 220 @ 100MHZ C53 0.1uF 0201 C55 0.1uF 0201 1 1 USB_SSRXM_DN3 USB_SSRXP_DN3 USB_SSTXM_DN3 1 1 1 USB_SSTXP_DN3 1 USB3_TYPEA_CONNECTOR C56 0.1uF C57 0.001uF R19 1M 0402 C58 0.1uF C59 0.001uF R20 1M 0402 Copyright © 2017, Texas Instruments Incorporated Figure 3. USB Port Connections 10 TUSB8044RGC REVD EVM Schematics SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback Copyright © 2017–2019, Texas Instruments Incorporated Appendix B www.ti.com DOWNSTREAM PORT POWER SWITCHES BOARD_3P3V BOARD_5V 5V INPUT BOARD_5V SW3 R26 10K 0402 C66 0.1uF SILKSCREEN: TIP +5v J6 U7 2 3 1 S T C82 10uF 2.1mm x 5.5mm 1 PWRON1_BATEN1 1 2 3 4 PWRON1_BATEN1 GND IN IN EN OUT OUT OUT FLT PAD 8 7 6 5 DN1_VBUS DN1_VBUS 2 OVERCUR1Z_TDI 1 9 C69 TPS2001C C70 150uF + 0.1uF C61 10uF D5 R30 330 0402 BOARD_3P3V BOARD_5V R27 10K 0402 C75 0.1uF U8 BOARD_5V 3.3V REGULATOR 1 BOARD_3P3V PWRON2_BATEN2 1 2 3 4 PWRON2_BATEN2 GND IN IN EN OUT OUT OUT FLT PAD C71 150uF + TPS7A4533 SENSE 2 1 D6 4 5 C68 10uF GND SHDN/ GND OUT R31 330 0402 D4 LED Green 0805 BOARD_3P3V BOARD_5V 6 C67 10uF IN DN2_VBUS OVERCUR2Z_TMS C72 0.1uF 3 1 DN2_VBUS 9 TPS2001C U4 2 8 7 6 5 R28 330 0402 R29 10K 0402 C78 0.1uF U9 1 PWRON3_BATEN3 1 2 3 4 PWRON3_BATEN3 GND IN IN EN OUT OUT OUT FLT PAD 8 7 6 5 DN3_VBUS + 0.1uF C76 150uF R35 330 0402 1P1V_SS BOARD_1P1V R32 NOPOP BOARD_3P3V BOARD_5V 2 3 4 13 14 17 15 NC1 NC2 NC3 NC4 NC5 NC6 SS GND 21 BIAS TPS74801RGW OUT1 OUT2 OUT3 OUT4 FB GND 10 IN1 IN2 IN3 IN4 EN 12 C73 10uF 5 6 7 8 11 1 D7 1.1V REGULATOR U6 2 OVERCUR3Z_TCK C77 TPS2001C BOARD_3P3V DN3_VBUS 9 PG 9 R36 10K 0402 C81 1 18 19 20 16 0.1uF R33 1.87K 0402 U10 1 2 3 4 1P1V_FB C74 10uF 1 PWRON4_BATEN4 PWRON4_BATEN4 R34 4.99K 0402 GND IN IN EN OUT OUT OUT FLT PAD TPS2001C 8 7 6 5 DN4_VBUS DN4_VBUS 2 9 C80 0.1uF + C79 150uF D8 R37 330 0402 Copyright © 2017, Texas Instruments Incorporated Figure 4. Power SLLU261A – April 2017 – Revised February 2019 Submit Documentation Feedback TUSB8044RGC REVD EVM Schematics Copyright © 2017–2019, Texas Instruments Incorporated 11 Revision History www.ti.com Revision History NOTE: Page numbers for previous revisions may differ from page numbers in the current version. Changes from Original (April 2017) to A Revision .......................................................................................................... Page • 12 ............................................................................................................................................... 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