KSZ8091MNX/KSZ8091RNB 10Base-T/100Base-TX Physical Layer Transceiver Revision 1.2 General Description Features The KSZ8091 is a single-supply 10Base-T/100Base-TX Ethernet physical-layer transceiver for transmission and reception of data over standard CAT-5 unshielded twisted pair (UTP) cable. • Single-chip 10Base-T/100Base-TX IEEE 802.3 compliant Ethernet transceiver • MII interface support (KSZ8091MNX) • RMII v1.2 interface support with a 50MHz reference clock output to MAC, and an option to input a 50MHz reference clock (KSZ8091RNB) • Back-to-back mode support for a 100Mbps copper repeater • MDC/MDIO management interface for PHY register configuration • Programmable interrupt output • LED outputs for link and activity status indication, plus speed indication for KSZ8091RNB • On-chip termination resistors for the differential pairs • Baseline wander correction • HP Auto MDI/MDI-X to reliably detect and correct straight-through and crossover cable connections with disable and enable option • Auto-negotiation to automatically select the highest linkup speed (10/100Mbps) and duplex (half/full) • Energy Efficient Ethernet (EEE) support with low-power idle (LPI) mode and clock stoppage (MII version only) for 100Base-TX and transmit amplitude reduction with 10Base-Te option • Wake-on-LAN (WOL) support with either magic packet, link status change, or robust custom-packet detection • HBM ESD rating (6kV) The KSZ8091 is a highly-integrated PHY solution. It reduces board cost and simplifies board layout by using on-chip termination resistors for the differential pairs, by integrating a low-noise regulator to supply the 1.2V core, and by offering a flexible 1.8/2.5/3.3V digital I/O interface. The KSZ8091MNX offers the Media Independent Interface (MII) and the KSZ8091RNB offers the Reduced Media Independent Interface (RMII) for direct connection with MII/RMII-compliant Ethernet MAC processors and switches. Energy Efficient Ethernet (EEE) provides further power saving during idle traffic periods and Wake-on-LAN (WOL) provides a mechanism for the KSZ8091 to wake up a system that is in standby power mode. The KSZ8091 provides diagnostic features to facilitate system bring-up and debugging in production testing and in product deployment. Parametric NAND tree support enables fault detection between KSZ8091 I/Os and the ® board. Micrel LinkMD TDR-based cable diagnostics identify faulty copper cabling. The KSZ8091MNX and KSZ8091RNB are available in 32pin, lead-free QFN packages (see “Ordering Information”). Datasheets and support documentation are available on website at: www.micrel.com. Functional Diagram LinkMD is a registered trademark of Micrel, Inc. Micrel Inc. • 2180 Fortune Drive • San Jose, CA 95131 • USA • tel +1 (408) 944-0800 • fax + 1 (408) 474-1000 • http://www.micrel.com August 31, 2015 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Features (Continued) Applications • Power-down and power-saving modes • LinkMD TDR-based cable diagnostics to identify faulty copper cabling • Parametric NAND Tree support for fault detection between chip I/Os and the board • Loopback modes for diagnostics • Single 3.3V power supply with VDD I/O options for 1.8V, 2.5V, or 3.3V • Built-in 1.2V regulator for core • Available in 32-pin (5mm × 5mm) QFN package • • • • • • Game console IP phone IP set-top box IP TV LOM Printer Description Ordering Information Part Number Temperature Range Package Lead Finish KSZ8091MNXCA 0°C to +70°C 32-Pin QFN Pb-Free MII, EEE and WoL Support, Commercial Temperature. KSZ8091MNXIA −40°C to +85°C 32-Pin QFN Pb-Free MII, EEE and WoL Support, Industrial Temperature. KSZ8091RNBCA 0°C to +70°C 32-Pin QFN Pb-Free RMII with 25MHz crystal/clock input and 50MHz RMII REF_CLK output (power-up default), EEE and WoL Support, Commercial Temperature. −40°C to +85°C 32-Pin QFN Pb-Free RMII with 25MHz crystal/clock input and 50MHz RMII REF_CLK output (power-up default), EEE and WoL Support, Industrial Temperature. (1) (1) KSZ8091RNBIA KSZ8091MNX Evaluation Board KSZ8091MNX-EVAL (Mounted with KSZ8091MNX device in commercial temperature) KSZ8091RNB Evaluation Board KSZ8091RNB-EVAL (Mounted with KSZ8091RNB device in commercial temperature) Note: 1. Contact factory for lead time. August 31, 2015 2 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Revision History Revision Date Summary of Changes 1.0 7/2/2013 New datasheet. 1.1 12/8/14 Added silver wire bonding part numbers to Order Information. Updated Ordering Information to include Ordering Part Number and Device Marking. 1.2 8/31/15 Add Max frequency for MDC in MII Management (MIIM) Interface section. Updated ordering information Table. Updated descriptions for Figure 27. Add a note for Figure 28. Updated descriptions in local loopback section for data loopback path. Updated Table 20 and Table 24. Add a note for Table 26. Updated description and add an equation in LinkMD section. Add HBM ESD rating in Features. August 31, 2015 3 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Contents List of Figures .......................................................................................................................................................................... 6 List of Tables ........................................................................................................................................................................... 7 Pin Configuration – KSZ8091MNX ......................................................................................................................................... 8 Pin Description – KSZ8091MNX ............................................................................................................................................. 8 Strapping Options – KSZ8091MNX ...................................................................................................................................... 12 Pin Configuration – KSZ8091RNB ........................................................................................................................................ 13 Pin Description – KSZ8091RNB ........................................................................................................................................... 13 Strapping Options – KSZ8091RNB ....................................................................................................................................... 17 Functional Description: 10Base-T/100Base-TX Transceiver ................................................................................................ 18 100Base-TX Transmit........................................................................................................................................................ 18 100Base-TX Receive ......................................................................................................................................................... 18 Scrambler/De-Scrambler (100Base-TX Only) ................................................................................................................... 18 10Base-T Transmit ............................................................................................................................................................ 18 10Base-T Receive ............................................................................................................................................................. 19 SQE and Jabber Function (10Base-T Only)...................................................................................................................... 19 PLL Clock Synthesizer ...................................................................................................................................................... 19 Auto-Negotiation ................................................................................................................................................................ 19 MII Data Interface (KSZ8091MNX only) ............................................................................................................................... 21 MII Signal Definition ........................................................................................................................................................... 21 MII Signal Diagram ............................................................................................................................................................ 23 RMII Data Interface (KSZ8091RNB only) ............................................................................................................................. 24 RMII – 25MHz Clock Mode................................................................................................................................................ 24 RMII – 50MHz Clock Mode................................................................................................................................................ 24 RMII Signal Definition ........................................................................................................................................................ 24 RMII Signal Diagram ......................................................................................................................................................... 25 Back-to-Back Mode – 100Mbps Copper Repeater ............................................................................................................... 27 MII Back-to-Back Mode (KSZ8091MNX only) ................................................................................................................... 27 RMII Back-to-Back Mode (KSZ8091RNB only) ................................................................................................................. 28 MII Management (MIIM) Interface ......................................................................................................................................... 29 Interrupt (INTRP) ................................................................................................................................................................... 29 HP Auto MDI/MDI-X .............................................................................................................................................................. 30 Straight Cable .................................................................................................................................................................... 30 Crossover Cable ................................................................................................................................................................ 31 Loopback Mode ..................................................................................................................................................................... 32 Local (Digital) Loopback .................................................................................................................................................... 32 Remote (Analog) Loopback ............................................................................................................................................... 33 ® LinkMD Cable Diagnostic .................................................................................................................................................... 34 NAND Tree Support .............................................................................................................................................................. 35 NAND Tree I/O Testing ..................................................................................................................................................... 36 Power Management .............................................................................................................................................................. 37 Power-Saving Mode .......................................................................................................................................................... 37 Energy-Detect Power-Down Mode .................................................................................................................................... 37 Power-Down Mode ............................................................................................................................................................ 37 Slow-Oscillator Mode ......................................................................................................................................................... 37 August 31, 2015 4 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Energy Efficient Ethernet (EEE) ............................................................................................................................................ 38 Transmit Direction Control (MAC-to-PHY) ........................................................................................................................ 39 Receive Direction Control (PHY-to-MAC) ......................................................................................................................... 40 Registers Associated with EEE ......................................................................................................................................... 41 Wake-On-LAN ....................................................................................................................................................................... 42 Magic-Packet Detection..................................................................................................................................................... 42 Customized-Packet Detection ........................................................................................................................................... 43 Link Status Change Detection ........................................................................................................................................... 43 Reference Circuit for Power and Ground Connections ......................................................................................................... 44 Typical Current/Power Consumption .................................................................................................................................... 45 Transceiver (3.3V), Digital I/Os (3.3V) .............................................................................................................................. 45 Transceiver (3.3V), Digital I/Os (2.5V) .............................................................................................................................. 45 Transceiver (3.3V), Digital I/Os (1.8V) .............................................................................................................................. 46 Register Map ......................................................................................................................................................................... 47 Standard Registers ............................................................................................................................................................... 49 IEEE-Defined Registers – Descriptions ............................................................................................................................. 49 Vendor-Specific Registers – Descriptions ......................................................................................................................... 54 MMD Registers...................................................................................................................................................................... 60 MMD Registers – Descriptions .......................................................................................................................................... 61 Absolute Maximum Ratings .................................................................................................................................................. 66 Operating Ratings ................................................................................................................................................................. 66 Electrical Characteristics ....................................................................................................................................................... 66 Timing Diagrams ................................................................................................................................................................... 68 MII SQE Timing (10Base-T) .............................................................................................................................................. 68 MII Transmit Timing (10Base-T) ........................................................................................................................................ 69 MII Receive Timing (10Base-T) ......................................................................................................................................... 70 MII Transmit Timing (100Base-TX) ................................................................................................................................... 71 MII Receive Timing (100Base-TX) .................................................................................................................................... 72 RMII Timing ....................................................................................................................................................................... 73 Auto-Negotiation Timing .................................................................................................................................................... 74 MDC/MDIO Timing ............................................................................................................................................................ 75 Power-Up/Reset Timing .................................................................................................................................................... 76 Reset Circuit .......................................................................................................................................................................... 77 Reference Circuits – LED Strap-In Pins ................................................................................................................................ 78 Reference Clock – Connection and Selection ...................................................................................................................... 79 Magnetic – Connection and Selection .................................................................................................................................. 80 Package Information ............................................................................................................................................................. 82 August 31, 2015 5 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB List of Figures Figure 1. Auto-Negotiation Flow Chart ................................................................................................................................. 20 Figure 2. KSZ8091MNX MII Interface .................................................................................................................................. 23 Figure 3. KSZ8091RNB RMII Interface (25MHz Clock Mode) ............................................................................................. 26 Figure 4. KSZ8091RNB RMII Interface (50MHz Clock Mode) ............................................................................................. 26 Figure 5. KSZ8091MNX/RNB to KSZ8091MNX/RNB Back-to-Back Copper Repeater ...................................................... 27 Figure 6. Typical Straight Cable Connection ....................................................................................................................... 30 Figure 7. Typical Crossover Cable Connection ................................................................................................................... 31 Figure 8. Local (Digital) Loopback ....................................................................................................................................... 32 Figure 9. Remote (Analog) Loopback .................................................................................................................................. 33 Figure 10. LPI Mode (Refresh Transmissions and Quiet Periods) ...................................................................................... 38 Figure 11. LPI Transition – MII (100Mbps) Transmit ........................................................................................................... 39 Figure 12. LPI Transition – RMII (100Mbps) Transmit ......................................................................................................... 39 Figure 13. LPI Transition – MII (100Mbps) Receive ............................................................................................................ 40 Figure 14. LPI Transition – RMII (100Mbps) Receive .......................................................................................................... 40 Figure 15. KSZ8091MNX/RNB Power and Ground Connections ........................................................................................ 44 Figure 16. MII SQE Timing (10Base-T) ............................................................................................................................... 68 Figure 17. MII Transmit Timing (10Base-T) ......................................................................................................................... 69 Figure 18. MII Receive Timing (10Base-T) .......................................................................................................................... 70 Figure 19. MII Transmit Timing (100Base-TX)..................................................................................................................... 71 Figure 20. MII Receive Timing (100Base-TX)...................................................................................................................... 72 Figure 21. RMII Timing – Data Received from RMII ............................................................................................................ 73 Figure 22. RMII Timing – Data Input to RMII ....................................................................................................................... 73 Figure 23. Auto-Negotiation Fast Link Pulse (FLP) Timing ................................................................................................. 74 Figure 24. MDC/MDIO Timing.............................................................................................................................................. 75 Figure 25. Power-Up/Reset Timing ...................................................................................................................................... 76 Figure 26. Recommended Reset Circuit .............................................................................................................................. 77 Figure 27. Recommended Reset Circuit for Interfacing with CPU/FPGA Reset Output ..................................................... 77 Figure 28. Reference Circuits for LED Strapping Pins......................................................................................................... 78 Figure 29. 25MHz Crystal/Oscillator Reference Clock Connection ..................................................................................... 79 Figure 30. 50MHz Oscillator Reference Clock Connection ................................................................................................. 79 Figure 31. Typical Magnetic Interface Circuit ....................................................................................................................... 80 August 31, 2015 6 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB List of Tables Table 1. MII Signal Definition ............................................................................................................................................... 21 Table 2. RMII Signal Definition............................................................................................................................................. 24 Table 3. MII Signal Connection for MII Back-to-Back Mode (100Base-TX Copper Repeater) ............................................ 27 Table 4. RMII Signal Connection for RMII Back-to-Back Mode (100Base-TX Copper Repeater) ...................................... 28 Table 5. MII Management Frame Format for the KSZ8091MNX/RNB ................................................................................ 29 Table 6. MDI/MDI-X Pin Definition ....................................................................................................................................... 30 Table 7. NAND Tree Test Pin Order for KSZ8091MNX ....................................................................................................... 35 Table 8. NAND Tree Test Pin Order for KSZ8091RNB ....................................................................................................... 36 Table 9. KSZ8091MNX/RNB Power Pin Description ........................................................................................................... 44 Table 10. Typical Current/Power Consumption (VDDA_3.3 = 3.3V, VDDIO = 3.3V) .......................................................... 45 Table 11. Typical Current/Power Consumption (VDDA_3.3 = 3.3V, VDDIO = 2.5V) .......................................................... 45 Table 12. Typical Current/Power Consumption (VDDA_3.3 = 3.3V, VDDIO = 1.8V) .......................................................... 46 Table 13. Standard Registers Supported by KSZ8091MNX/RNB ....................................................................................... 47 Table 14. MMD Registers Supported by KSZ8091MNX/RNB ............................................................................................. 48 Table 15. Portal Registers (Access to Indirect MMD Registers) .......................................................................................... 60 Table 16. MII SQE Timing (10Base-T) Parameters ............................................................................................................. 68 Table 17. MII Transmit Timing (10Base-T) Parameters ...................................................................................................... 69 Table 18. MII Receive Timing (10Base-T) Parameters........................................................................................................ 70 Table 19. MII Transmit Timing (100Base-TX) Parameters .................................................................................................. 71 Table 20. MII Receive Timing (100Base-TX) Parameters ................................................................................................... 72 Table 21. RMII Timing Parameters – KSZ8091RNB (25MHz input to XI pin, 50MHz output from REF_CLK pin) ............. 73 Table 22. RMII Timing Parameters – KSZ8091RNB (50MHz input to XI pin) ..................................................................... 73 Table 23. Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters ............................................................................... 74 Table 24. MDC/MDIO Timing Parameters ........................................................................................................................... 75 Table 25. Power-Up/Reset Timing Parameters ................................................................................................................... 76 Table 26. 25MHz Crystal / Reference Clock Selection Criteria ........................................................................................... 79 Table 27. 50MHz Oscillator / Reference Clock Selection Criteria ....................................................................................... 79 Table 28. Magnetics Selection Criteria ................................................................................................................................ 81 Table 29. Compatible Single-Port 10/100 Magnetics........................................................................................................... 81 August 31, 2015 7 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Configuration – KSZ8091MNX 32-Pin (5mm × 5mm) QFN August 31, 2015 8 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Description – KSZ8091MNX Type (2) Pin Number Pin Name 1 GND GND 2 VDD_1.2 P Pin Function Ground 1.2V core VDD (power supplied by KSZ8091MNX) Decouple with 2.2µF and 0.1µF capacitors to ground. 3 VDDA_3.3 P 3.3V analog VDD 4 RXM I/O Physical receive or transmit signal (− differential) 5 RXP I/O Physical receive or transmit signal (+ differential) 6 TXM I/O Physical transmit or receive signal (− differential) 7 TXP I/O Physical transmit or receive signal (+ differential) 8 XO O Crystal feedback for 25MHz crystal This pin is a no connect if an oscillator or external clock source is used. 9 XI I Crystal/Oscillator/External Clock input 25MHz ±50ppm 10 REXT I Set PHY transmit output current Connect a 6.49kΩ resistor to ground on this pin. 11 MDIO Ipu/Opu Management Interface (MII) Data I/O This pin has a weak pull-up, is open-drain, and requires an external 1.0kΩ pull-up resistor. 12 MDC Ipu Management Interface (MII) Clock input This clock pin is synchronous to the MDIO data pin. 13 RXD3/ PHYAD0 Ipu/O MII mode: MII Receive Data Output[3] (3) Config mode: The pull-up/pull-down value is latched as PHYADDR[0] at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. Notes: 2. P = Power supply. GND = Ground. I = Input. O = Output. I/O = Bi-directional. Ipu = Input with internal pull-up (see “Electrical Characteristics” for value). Ipd = Input with internal pull-down (see “Electrical Characteristics” for value). Ipu/O = Input with internal pull-up (see “Electrical Characteristics” for value) during power-up/reset; output pin otherwise. Ipd/O = Input with internal pull-down (see “Electrical Characteristics” for value) during power-up/reset; output pin otherwise. Ipu/Opu = Input with internal pull-up (see “Electrical Characteristics” for value) and output with internal pull-up (see “Electrical Characteristics” for value). 3. MII RX Mode: The RXD[3:0] bits are synchronous with RXC. When RXDV is asserted, RXD[3:0] presents valid data to the MAC. 4. MII TX Mode: The TXD[3:0] bits are synchronous with TXC. When TXEN is asserted, TXD[3:0] presents valid data from the MAC. August 31, 2015 9 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Description – KSZ8091MNX (Continued) Pin Number Pin Name 14 RXD2/ Type (2) Ipd/O PHYAD1 Pin Function MII mode: MII Receive Data Output[2] (3) Config mode: The pull-up/pull-down value is latched as PHYADDR[1] at the deassertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 15 RXD1/ Ipd/O PHYAD2 MII mode: MII Receive Data Output[1] (3) Config mode: The pull-up/pull-down value is latched as PHYADDR[2] at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 16 RXD0/ Ipu/O DUPLEX MII mode: MII Receive Data Output[0] (3) Config mode: The pull-up/pull-down value is latched as DUPLEX at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 17 VDDIO P 18 RXDV/ Ipd/O CONFIG2 3.3V, 2.5V, or 1.8V digital VDD MII mode: MII Receive Data Valid output Config mode: The pull-up/pull-down value is latched as CONFIG2 at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 19 RXC/ Ipd/O B-CAST_OFF MII mode: MII Receive Clock output Config mode: The pull-up/pull-down value is latched as B-CAST_OFF at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 20 RXER/ Ipd/O ISO MII mode: MII Receive Error output Config mode: The pull-up/pull-down value is latched as ISOLATE at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 21 INTRP/ Ipu/Opu PME_N2/ NAND_Tree# Interrupt output: Programmable interrupt output, with Register 1Bh as the Interrupt Control/Status register, for programming the interrupt conditions and reading the interrupt status. Register 1Fh, bit [9] sets the interrupt output to active low (default) or active high. PME_N output: Programmable PME_N output (pin option 2). When asserted low, this pin signals that a WOL event has occurred. Config mode: The pull-up/pull-down value is latched as NAND Tree# at the deassertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. This pin has a weak pull-up and is an open-drain. For Interrupt (when active low) and PME functions, this pin requires an external 1.0kΩ pull-up resistor to VDDIO (digital VDD). 22 TXC/ Ipd/O PME_EN MII mode: MII Transmit Clock output MII back-to-back mode: MII Transmit Clock input Config mode: The pull-up/pull-down value is latched as PME_EN at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 23 August 31, 2015 TXEN I MII mode: MII Transmit Enable input 10 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Description – KSZ8091MNX (Continued) Type (2) Pin Number Pin Name 24 TXD0 I MII mode: MII Transmit Data Input[0] (4 ) 25 TXD1 I MII mode: MII Transmit Data Input[1] (4 ) 26 TXD2 I MII mode: MII Transmit Data Input[2] (4 ) 27 TXD3 I MII Mode: MII Transmit Data Input[3] (4 ) 28 COL/ Ipd/O MII mode: MII Collision Detect output CONFIG0 Pin Function Config mode: The pull-up/pull-down value is latched as CONFIG0 at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 29 CRS/ Ipd/O CONFIG1 MII mode: MII Carrier Sense output Config mode: The pull-up/pull-down value is latched as CONFIG1 at the de-assertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. 30 LED0/ Ipu/O PME_N1/ LED output: Programmable LED0 output PME_N Output: Programmable PME_N Output (pin option 1) In this mode, this pin has a weak pull-up, is an open-drain, and requires an external 1.0kΩ pull-up resistor to VDDIO (digital VDD). Config mode: NWAYEN Latched as auto-negotiation enable (Register 0h, bit [12]) at the deassertion of reset. See the “Strapping Options – KSZ8091MNX” section for details. The LED0 pin is programmable using Register 1Fh bits [5:4], and is defined as follows. LED mode = [00] Link/Activity Pin State LED Definition No link High OFF Link Low ON Activity Toggle Blinking Link Pin State LED Definition No link High OFF Link Low ON LED mode = [01] LED mode = [10], [11] 31 TXER Ipd Reserved MII mode: MII Transmit Error input For EEE mode, this pin is driven by the EEE-MAC to put the KSZ8091MNX transmit into the LPI state. For non-EEE mode, this pin is not defined for error transmission from MAC to KSZ8091MNX and can be left as a no connect. 32 RST# Ipu PADDLE GND GND August 31, 2015 Chip reset (active low) Ground 11 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Strapping Options – KSZ8091MNX (5 ) Pin Number Pin Name 15 PHYAD2 Ipd/O 14 PHYAD1 Ipd/O 13 PHYAD0 Ipu/O Type Pin Function PHYAD[2:0] is latched at de-assertion of reset and is configurable to any value from 0 to 7 with PHY Address 1 as the default value. PHY Address 0 is assigned by default as the broadcast PHY address, but it can be assigned as a unique PHY address after pulling the B-CAST_OFF strapping pin high or writing a ‘1’ to Register 16h, bit [9]. PHY Address bits [4:3] are set to 00 by default. 18 CONFIG2 Ipd/O 29 CONFIG1 Ipd/O CONFIG[2:0] Mode 28 CONFIG0 Ipd/O 000 MII (default) 110 MII back-to-back 001–101, 111 Reserved – not used 22 PME_EN Ipd/O The CONFIG[2:0] strap-in pins are latched at the de-assertion of reset. PME output for Wake-on-LAN Pull-up = Enable Pull-down (default) = Disable At the de-assertion of reset, this pin value is latched into Register 16h, bit [15]. 20 ISO Ipd/O Isolate mode Pull-up = Enable Pull-down (default) = Disable At the de-assertion of reset, this pin value is latched into Register 0h, bit [10]. 16 DUPLEX Ipu/O Duplex mode Pull-up (default) = Half-duplex Pull-down = Full-duplex At the de-assertion of reset, this pin value is latched into Register 0h, bit [8]. 30 NWAYEN Ipu/O Nway auto-negotiation enable Pull-up (default) = Enable auto-negotiation Pull-down = Disable auto-negotiation At the de-assertion of reset, this pin value is latched into Register 0h, bit [12]. 19 B-CAST_OFF Ipd/O Broadcast off – for PHY Address 0 Pull-up = PHY Address 0 is set as an unique PHY address Pull-down (default) = PHY Address 0 is set as a broadcast PHY address At the de-assertion of reset, this pin value is latched by the chip. 21 NAND_Tree# Ipu/Opu NAND tree mode Pull-up (default) = Disable Pull-down = Enable At the de-assertion of reset, this pin value is latched by the chip. Note: 5. Ipu/O = Input with internal pull-up (see “Electrical Characteristics” for value) during power-up/reset; output pin otherwise. Ipd/O = Input with internal pull-down (see “Electrical Characteristics” for value) during power-up/reset; output pin otherwise. Ipu/Opu = Input with internal pull-up (see “Electrical Characteristics” for value) and output with internal pull-up (see “Electrical Characteristics” for value). The strap-in pins are latched at the de-assertion of reset. In some systems, the MAC MII receive input pins may drive high/low during power-up or reset, and consequently cause the PHY strap-in pins on the MII signals to be latched to unintended high/low states. In this case, external pull-ups (4.7kΩ) or pull-downs (1.0kΩ) should be added on these PHY strap-in pins to ensure that the intended values are strapped-in correctly. August 31, 2015 12 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Configuration – KSZ8091RNB 32-Pin (5mm × 5mm) QFN August 31, 2015 13 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Description – KSZ8091RNB Type (6) Pin Number Pin Name 1 GND GND 2 VDD_1.2 P Pin Function Ground 1.2V core VDD (power supplied by KSZ8091RNB) Decouple with 2.2µF and 0.1µF capacitors to ground. 3 VDDA_3.3 P 3.3V analog VDD 4 RXM I/O Physical receive or transmit signal (− differential) 5 RXP I/O Physical receive or transmit signal (+ differential) 6 TXM I/O Physical transmit or receive signal (− differential) 7 TXP I/O Physical transmit or receive signal (+ differential) 8 XO O Crystal feedback for 25MHz crystal This pin is a no connect if an oscillator or external clock source is used. 9 10 XI REXT I I 25MHz Mode: 25MHz ±50ppm Crystal/Oscillator/External Clock Input 50MHz Mode: 50MHz ±50ppm Oscillator/External Clock Input Set PHY transmit output current Connect a 6.49kΩ resistor to ground on this pin. 11 MDIO Ipu/Opu Management Interface (MII) Data I/O This pin has a weak pull-up, is open-drain, and requires an external 1.0kΩ pull-up resistor. 12 MDC Ipu Management Interface (MII) Clock input This clock pin is synchronous to the MDIO data pin. 13 PHYAD0 Ipu/O The pull-up/pull-down value is latched as PHYADDR[0] at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. Notes: 6. P = Power supply. GND = Ground. I = Input. O = Output. I/O = Bi-directional. Ipu = Input with internal pull-up (see “Electrical Characteristics” for value). Ipu/O = Input with internal pull-up (see “Electrical Characteristics” for value) during power-up/reset; output pin otherwise. Ipd/O = Input with internal pull-down (see “Electrical Characteristics” for value) during power-up/reset; output pin otherwise. Ipu/Opu = Input with internal pull-up (see “Electrical Characteristics” for value) and output with internal pull-up (see “Electrical Characteristics” for value). NC = Pin is not bonded to the die. 7. RMII RX Mode: The RXD[1:0] bits are synchronous with the 50MHz RMII Reference Clock. For each clock period in which CRS_DV is asserted, two bits of recovered data are sent by the PHY to the MAC. 8. RMII TX Mode: The TXD[1:0] bits are synchronous with the 50MHz RMII Reference Clock. For each clock period in which TXEN is asserted, two bits of data are received by the PHY from the MAC. August 31, 2015 14 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Description – KSZ8091RNB (Continued) Pin Number Pin Name 14 PHYAD1 Type (6) Ipd/O Pin Function The pull-up/pull-down value is latched as PHYADDR[1] at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 15 RXD1/ Ipd/O PHYAD2 RMII mode: RMII Receive Data Output[1] (7 ) Config mode: The pull-up/pull-down value is latched as PHYADDR[2] at the deassertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 16 RXD0/ Ipu/O DUPLEX RMII mode: RMII Receive Data Output[0] (7 ) Config mode: The pull-up/pull-down value is latched as DUPLEX at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 17 VDDIO P 18 CRS_DV/ Ipd/O CONFIG2 3.3V, 2.5V, or 1.8V digital VDD RMII mode: RMII Carrier Sense/Receive Data Valid output Config mode: The pull-up/pull-down value is latched as CONFIG2 at the deassertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 19 REF_CLK/ Ipd/O B-CAST_OFF RMII mode: 25MHz mode: This pin provides the 50MHz RMII reference clock output to the MAC. See also XI (pin 9). 50MHz mode: This pin is a no connect. See also XI (pin 9). Config mode: The pull-up/pull-down value is latched as B-CAST_OFF at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 20 RXER/ Ipd/O ISO RMII mode: RMII Receive Error output Config mode: The pull-up/pull-down value is latched as ISOLATE at the deassertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 21 INTRP/ Ipu/Opu PME_N2/ NAND_Tree# Interrupt output: Programmable interrupt output, with Register 1Bh as the Interrupt Control/Status register, for programming the interrupt conditions and reading the interrupt status. Register 1Fh, bit [9] sets the interrupt output to active low (default) or active high. PME_N output: Programmable PME_N output (pin option 2). When asserted low, this pin signals that a WOL event has occurred. Config mode: The pull-up/pull-down value is latched as NAND Tree# at the deassertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. This pin has a weak pull-up and is an open-drain. For Interrupt (when active low) and PME functions, this pin requires an external 1.0kΩ pull-up resistor to VDDIO (digital VDD). 22 PME_EN Ipd/O The pull-up/pull-down value is latched as PME_EN at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 23 TXEN I RMII Transmit Enable input 24 TXD0 I RMII Transmit Data Input[0] (8 ) 25 TXD1 I RMII Transmit Data Input[1] (8 ) 26 NC NC August 31, 2015 No connect – This pin is not bonded and can be left floating. 15 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Pin Description – KSZ8091RNB (Continued) Type (6) Pin Number Pin Name 27 NC NC 28 CONFIG0 Ipd/O Pin Function No connect – This pin is not bonded and can be left floating. The pull-up/pull-down value is latched as CONFIG0 at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 29 CONFIG1 Ipd/O The pull-up/pull-down value is latched as CONFIG1 at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. 30 LED0/ Ipu/O PME_N1/ LED output: Programmable LED0 output PME_N Output: Programmable PME_N Output (pin option 1). In this mode, this pin has a weak pull-up, is an open-drain, and requires an external 1.0kΩ pull-up resistor to VDDIO (digital VDD). Config mode: Latched as auto-negotiation enable (Register 0h, bit [12]) at the deassertion of reset. NWAYEN See the “Strapping Options – KSZ8091RNB” section for details. The LED0 pin is programmable using Register 1Fh bits [5:4], and is defined as follows. LED mode = [00] Link/Activity Pin State LED Definition No link High OFF Link Low ON Activity Toggle Blinking Link Pin State LED Definition No link High OFF Link Low ON LED mode = [01] LED mode = [10], [11] 31 LED1/ Ipu/O SPEED Reserved LED output: Programmable LED1 output Config mode: Latched as Speed (Register 0h, bit [13]) at the de-assertion of reset. See the “Strapping Options – KSZ8091RNB” section for details. The LED1 pin is programmable using Register 1Fh bits [5:4], and is defined as follows. LED mode = [00] Speed Pin State LED Definition 10Base-T High OFF 100Base-TX Low ON Activity Pin State LED Definition No activity High OFF Activity Toggle Blinking LED mode = [01] LED mode = [10], [11] 32 RST# Ipu PADDLE GND GND August 31, 2015 Reserved Chip reset (active low) Ground 16 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Strapping Options – KSZ8091RNB (6 ) Pin Number Pin Name 15 PHYAD2 Ipd/O 14 PHYAD1 Ipd/O 13 PHYAD0 Ipu/O Type Pin Function PHYAD[2:0] is latched at de-assertion of reset and is configurable to any value from 0 to 7 with PHY Address 1 as the default value. PHY Address 0 is assigned by default as the broadcast PHY address, but it can be assigned as a unique PHY address after pulling the B-CAST_OFF strapping pin high or writing a ‘1’ to Register 16h, bit [9]. PHY Address bits [4:3] are set to 00 by default. 18 CONFIG2 Ipd/O 29 CONFIG1 Ipd/O CONFIG[2:0] Mode 28 CONFIG0 Ipd/O 001 RMII 101 RMII back-to-back 000, 010–100, 110, 111 Reserved – not used 22 PME_EN Ipd/O The CONFIG[2:0] strap-in pins are latched at the de-assertion of reset. PME output for Wake-on-LAN Pull-up = Enable Pull-down (default) = Disable At the de-assertion of reset, this pin value is latched into Register 16h, bit [15]. 20 ISO Ipd/O Isolate mode Pull-up = Enable Pull-down (default) = Disable At the de-assertion of reset, this pin value is latched into register 0h, bit [10]. 31 SPEED Ipu/O Speed mode Pull-up (default) = 100Mbps Pull-down = 10Mbps At the de-assertion of reset, this pin value is latched into Register 0h, bit [13] as the speed select, and also is latched into Register 4h (auto-negotiation advertisement) as the speed capability support. 16 DUPLEX Ipu/O Duplex mode Pull-up (default) = Half-duplex Pull-down = Full-duplex At the de-assertion of reset, this pin value is latched into Register 0h, bit [8]. 30 NWAYEN Ipu/O Nway auto-negotiation enable Pull-up (default) = Enable auto-negotiation Pull-down = Disable auto-negotiation At the de-assertion of reset, this pin value is latched into Register 0h, bit [12]. 19 B-CAST_OFF Ipd/O Broadcast off – for PHY Address 0 Pull-up = PHY Address 0 is set as an unique PHY address Pull-down (default) = PHY Address 0 is set as a broadcast PHY address At the de-assertion of reset, this pin value is latched by the chip. 21 NAND_Tree# Ipu/Opu NAND tree mode Pull-up (default) = Disable Pull-down = Enable At the de-assertion of reset, this pin value is latched by the chip. The strap-in pins are latched at the de-assertion of reset. In some systems, the MAC RMII receive input pins may drive high/low during power-up or reset, and consequently cause the PHY strap-in pins on the RMII signals to be latched to unintended high/low states. In this case, external pull-ups (4.7kΩ) or pull-downs (1.0kΩ) should be added on these PHY strap-in pins to ensure that the intended values are strapped-in correctly. August 31, 2015 17 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Functional Description: 10Base-T/100Base-TX Transceiver The KSZ8091 is an integrated single 3.3V supply Fast Ethernet transceiver. It is fully compliant with the IEEE 802.3 Specification, and reduces board cost and simplifies board layout by using on-chip termination resistors for the two differential pairs and by integrating the regulator to supply the 1.2V core. On the copper media side, the KSZ8091 supports 10Base-T and 100Base-TX for transmission and reception of data over a standard CAT-5 unshielded twisted pair (UTP) cable, and HP Auto MDI/MDI-X for reliable detection of and correction for straight-through and crossover cables. On the MAC processor side, the KSZ8091MNX offers the Media Independent Interface (MII) and the KSZ8091RNB offers the Reduced Media Independent Interface (RMII) for direct connection with MII and RMII compliant Ethernet MAC processors and switches, respectively. The MII management bus option gives the MAC processor complete access to the KSZ8091 control and status registers. Additionally, an interrupt pin eliminates the need for the processor to poll for PHY status change. The KSZ8091MNX/RNB is used to refer to both KSZ8091MNX and KSZ8091RNB versions in this datasheet. 100Base-TX Transmit The 100Base-TX transmit function performs parallel-to-serial conversion, 4B/5B encoding, scrambling, NRZ-to-NRZI conversion, and MLT3 encoding and transmission. The circuitry starts with a parallel-to-serial conversion, which converts the MII/RMII data from the MAC into a 125MHz serial bit stream. The data and control stream is then converted into 4B/5B coding and followed by a scrambler. The serialized data is further converted from NRZ-to-NRZI format, and then transmitted in MLT3 current output. The output current is set by an external 6.49kΩ 1% resistor for the 1:1 transformer ratio. The output signal has a typical rise/fall time of 4ns and complies with the ANSI TP-PMD standard regarding amplitude balance, overshoot, and timing jitter. The wave-shaped 10Base-T output is also incorporated into the 100Base-TX transmitter. 100Base-TX Receive The 100Base-TX receiver function performs adaptive equalization, DC restoration, MLT3-to-NRZI conversion, data and clock recovery, NRZI-to-NRZ conversion, de-scrambling, 4B/5B decoding, and serial-to-parallel conversion. The receiving side starts with the equalization filter to compensate for inter-symbol interference (ISI) over the twisted pair cable. Because the amplitude loss and phase distortion is a function of the cable length, the equalizer must adjust its characteristics to optimize performance. In this design, the variable equalizer makes an initial estimation based on comparisons of incoming signal strength against some known cable characteristics, then tunes itself for optimization. This is an ongoing process and self-adjusts against environmental changes such as temperature variations. Next, the equalized signal goes through a DC-restoration and data-conversion block. The DC-restoration circuit compensates for the effect of baseline wander and improves the dynamic range. The differential data-conversion circuit converts MLT3 format back to NRZI. The slicing threshold is also adaptive. The clock-recovery circuit extracts the 125MHz clock from the edges of the NRZI signal. This recovered clock is then used to convert the NRZI signal to NRZ format. This signal is sent through the de-scrambler, then the 4B/5B decoder. Finally, the NRZ serial data is converted to MII/RMII format and provided as the input data to the MAC. Scrambler/De-Scrambler (100Base-TX Only) The scrambler spreads the power spectrum of the transmitted signal to reduce electromagnetic interference (EMI) and baseline wander. The de-scrambler recovers the scrambled signal. 10Base-T Transmit The 10Base-T drivers are incorporated with the 100Base-TX drivers to allow for transmission using the same magnetic. The drivers perform internal wave-shaping and pre-emphasis, and output 10Base-T signals with a typical amplitude of 2.5V peak for standard 10Base-T mode and 1.75V peak for energy-efficient 10Base-Te mode. The 10Base-T/10Base-Te signals have harmonic contents that are at least 27dB below the fundamental frequency when driven by an all-ones Manchester-encoded signal. August 31, 2015 18 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB 10Base-T Receive On the receive side, input buffer and level detecting squelch circuits are used. A differential input receiver circuit and a phase-locked loop (PLL) performs the decoding function. The Manchester-encoded data stream is separated into clock signal and NRZ data. A squelch circuit rejects signals with levels less than 400mV, or with short pulse widths, to prevent noise at the RXP and RXM inputs from falsely triggering the decoder. When the input exceeds the squelch limit, the PLL locks onto the incoming signal and the KSZ8091MNX/RNB decodes a data frame. The receive clock is kept active during idle periods between data receptions. SQE and Jabber Function (10Base-T Only) In 10Base-T operation, a short pulse is put out on the COL pin after each frame is transmitted. This SQE test is needed to test the 10Base-T transmit/receive path. If transmit enable (TXEN) is high for more than 20ms (jabbering), the 10Base-T transmitter is disabled and COL is asserted high. If TXEN is then driven low for more than 250ms, the 10Base-T transmitter is re-enabled and COL is de-asserted (returns to low). PLL Clock Synthesizer The KSZ8091MNX/RNB generates all internal clocks and all external clocks for system timing from an external 25MHz crystal, oscillator, or reference clock. For the KSZ8091RNB in RMII 50MHz clock mode, these clocks are generated from an external 50MHz oscillator or system clock. Auto-Negotiation The KSZ8091MNX/RNB conforms to the auto-negotiation protocol, defined in Clause 28 of the IEEE 802.3 Specification. Auto-negotiation allows unshielded twisted pair (UTP) link partners to select the highest common mode of operation. During auto-negotiation, link partners advertise capabilities across the UTP link to each other and then compare their own capabilities with those they received from their link partners. The highest speed and duplex setting that is common to the two link partners is selected as the mode of operation. The following list shows the speed and duplex operation mode from highest to lowest priority. • Priority 1: 100Base-TX, full-duplex • Priority 2: 100Base-TX, half-duplex • Priority 3: 10Base-T, full-duplex • Priority 4: 10Base-T, half-duplex If auto-negotiation is not supported or the KSZ8091MNX/RNB link partner is forced to bypass auto-negotiation, then the KSZ8091MNX/RNB sets its operating mode by observing the signal at its receiver. This is known as parallel detection, which allows the KSZ8091MNX/RNB to establish a link by listening for a fixed signal protocol in the absence of the autonegotiation advertisement protocol. Auto-negotiation is enabled by either hardware pin strapping (NWAYEN, pin 30) or software (Register 0h, bit [12]). By default, auto-negotiation is enabled after power-up or hardware reset. After that, auto-negotiation can be enabled or disabled by Register 0h, bit [12]. If auto-negotiation is disabled, the speed is set by Register 0h, bit [13], and the duplex is set by Register 0h, bit [8]. The auto-negotiation link-up process is shown in Figure 1. August 31, 2015 19 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Figure 1. Auto-Negotiation Flow Chart August 31, 2015 20 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MII Data Interface (KSZ8091MNX Only) The Media Independent Interface (MII) is compliant with the IEEE 802.3 Specification. It provides a common interface between MII PHYs and MACs, and has the following key characteristics: • Pin count is 16 pins (7 pins for data transmission, 7 pins for data reception, and 2 pins for carrier and collision indication). • 10Mbps and 100Mbps data rates are supported at both half- and full-duplex. • Data transmission and reception are independent and belong to separate signal groups. • Transmit data and receive data are each 4 bits wide, a nibble. By default, the KSZ8091MNX is configured to MII mode after it is powered up or hardware reset with the following: • A 25MHz crystal connected to XI, XO (pins 9, 8), or an external 25MHz clock source (oscillator) connected to XI. • The CONFIG[2:0] strapping pins (pins 18, 29, 28) set to 000 (default setting). MII Signal Definition Table 1 describes the MII signals. Refer to Clause 22 of the IEEE 802.3 Specification for detailed information. Table 1. MII Signal Definition Direction (with respect to PHY, KSZ8091MNX signal) Direction (with respect to MAC) Output Input TXEN Input Output Transmit Enable TXD[3:0] Input Output Transmit Data[3:0] MII Signal Name TXC Description Transmit Clock (2.5MHz for 10Mbps; 25MHz for 100Mbps) Transmit Error TXER Input Output, or (not implemented) RXC Output Input RXDV Output Input Receive Data Valid RXD[3:0] Output Input Receive Data[3:0] RXER Output Input, or (not required) Receive Error CRS Output Input Carrier Sense COL Output Input Collision Detection (KSZ8091MNX implements only the EEE function for this pin. See “Transmit Error (TXER)” for details.) Receive Clock (2.5MHz for 10Mbps; 25MHz for 100Mbps) Transmit Clock (TXC) TXC is sourced by the PHY. It is a continuous clock that provides the timing reference for TXEN, TXD[3:0] and TXER. TXC is 2.5MHz for 10Mbps operation and 25MHz for 100Mbps operation. Transmit Enable (TXEN) TXEN indicates that the MAC is presenting nibbles on TXD[3:0] for transmission. It is asserted synchronously with the first nibble of the preamble and remains asserted while all nibbles to be transmitted are presented on the MII. It is negated before the first TXC following the final nibble of a frame. TXEN transitions synchronously with respect to TXC. August 31, 2015 21 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Transmit Data[3:0] (TXD[3:0]) When TXEN is asserted, TXD[3:0] are the data nibbles presented by the MAC and accepted by the PHY for transmission. When TXEN is de-asserted, the MAC drives TXD[3:0] to either 0000 for the idle state (non-EEE mode) or 0001 for the LPI state (EEE mode). TXD[3:0] transitions synchronously with respect to TXC. Transmit Error (TXER) TXER is implemented only for the EEE function. For EEE mode, this pin is driven by the EEE-MAC to put the KSZ8091MNX transmit into the LPI state. For non-EEE mode, this pin is not defined for error transmission from MAC to KSZ8091MNX and can be left as a no connect. TXER transitions synchronously with respect to TXC. Receive Clock (RXC) RXC provides the timing reference for RXDV, RXD[3:0] and RXER. • In 10Mbps mode, RXC is recovered from the line while the carrier is active. When the line is idle or the link is down, RXC is derived from the PHY’s reference clock. • In 100Mbps mode, RXC is recovered continuously from the line. If the link is down, RXC is derived from the PHY’s reference clock. RXC is 2.5MHz for 10Mbps operation and 25MHz for 100Mbps operation. Receive Data Valid (RXDV) RXDV is driven by the PHY to indicate that the PHY is presenting recovered and decoded nibbles on RXD[3:0]. • In 10Mbps mode, RXDV is asserted with the first nibble of the start-of-frame delimiter (SFD), 5D, and remains asserted until the end of the frame. • In 100Mbps mode, RXDV is asserted from the first nibble of the preamble to the last nibble of the frame. RXDV transitions synchronously with respect to RXC. Receive Data[3:0] (RXD[3:0]) For each clock period in which RXDV is asserted, RXD[3:0] transfers a nibble of recovered data from the PHY. When RXDV is de-asserted, the PHY drives RXD[3:0] to either 0000 for the idle state (non-EEE mode) or 0001 for the LPI state (EEE mode). RXD[3:0] transitions synchronously with respect to RXC. Receive Error (RXER) When RXDV is asserted, RXER is asserted for one or more RXC periods to indicate that a symbol error (for example, a coding error that a PHY can detect that may otherwise be undetectable by the MAC sub-layer) is detected somewhere in the frame that is being transferred from the PHY to the MAC. In EEE mode only, when RXDV is de-asserted, RXER is driven by the PHY to inform the MAC that the KSZ8091MNX receive is in the LPI state. RXER transitions synchronously with respect to RXC. Carrier Sense (CRS) CRS is asserted and de-asserted as follows: • In 10Mbps mode, CRS assertion is based on the reception of valid preambles. CRS de-assertion is based on the reception of an end-of-frame (EOF) marker. August 31, 2015 22 Revision 1.2 Micrel, Inc. • KSZ8091MNX/KSZ8091RNB In 100Mbps mode, CRS is asserted when a start-of-stream delimiter or /J/K symbol pair is detected. CRS is deasserted when an end-of-stream delimiter or /T/R symbol pair is detected. Additionally, the PMA layer de-asserts CRS if IDLE symbols are received without /T/R. Collision (COL) COL is asserted in half-duplex mode whenever the transmitter and receiver are simultaneously active on the line. This informs the MAC that a collision has occurred during its transmission to the PHY. COL transitions asynchronously with respect to TXC and RXC. MII Signal Diagram The KSZ8091MNX MII pin connections to the MAC are shown in Figure 2. Figure 2. KSZ8091MNX MII Interface August 31, 2015 23 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB RMII Data Interface (KSZ8091RNB Only) The Reduced Media Independent Interface (RMII) specifies a low pin count Media Independent Interface (MII). It provides a common interface between physical layer and MAC layer devices, and has the following key characteristics: • Pin count is 8 pins (3 pins for data transmission, 4 pins for data reception, and 1 pin for the 50MHz reference clock). • 10Mbps and 100Mbps data rates are supported at both half- and full-duplex. • Data transmission and reception are independent and belong to separate signal groups. • Transmit data and receive data are each 2 bits wide, a dibit. RMII – 25MHz Clock Mode The KSZ8091RNB is configured to RMII – 25MHz clock mode after it is powered up or hardware reset with the following: • A 25MHz crystal connected to XI, XO (pins 9, 8), or an external 25MHz clock source (oscillator) connected to XI. • The CONFIG[2:0] strapping pins (pins 18, 29, 28) set to 001. • Register 1Fh, bit [7] is set to 0 (default value) to select 25MHz clock mode. RMII – 50MHz Clock Mode The KSZ8091RNB is configured to RMII – 50MHz clock mode after it is powered up or hardware reset with the following: • An external 50MHz clock source (oscillator) connected to XI (pin 9). • The CONFIG[2:0] strapping pins (pins 18, 29, 28) set to 001. • Register 1Fh, bit [7] is set to 1 to select 50MHz clock mode. RMII Signal Definition Table 2 describes the RMII signals. Refer to RMII Specification v1.2 for detailed information. Table 2. RMII Signal Definition Direction (with respect to PHY, KSZ8091RNB signal) Direction (with respect to MAC) Description Output (25MHz clock mode)/ <no connect> (50MHz clock mode) Input/ Input or <no connect> Synchronous 50MHz reference clock for receive, transmit, and control interface TXEN Input Output Transmit Enable TXD[1:0] Input Output Transmit Data[1:0] CRS_DV Output Input Carrier Sense/Receive Data Valid RXD[1:0] Output Input Receive Data[1:0] RXER Output Input, or (not required) RMII Signal Name REF_CLK Receive Error Reference Clock (REF_CLK) REF_CLK is a continuous 50MHz clock that provides the timing reference for TXEN, TXD[1:0], CRS_DV, RXD[1:0] and RX_ER. For 25MHz clock mode, the KSZ8091RNB generates and outputs the 50MHz RMII REF_CLK to the MAC at REF_CLK (pin 19). For 50MHz clock mode, the KSZ8091RNB takes in the 50MHz RMII REF_CLK from the MAC or system board at XI (pin 9) and leaves the REF_CLK (pin 19) as a no connect. August 31, 2015 24 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Transmit Enable (TXEN) TXEN indicates that the MAC is presenting dibits on TXD[1:0] for transmission. It is asserted synchronously with the first dibit of the preamble and remains asserted while all dibits to be transmitted are presented on the RMII. It is negated before the first REF_CLK following the final dibit of a frame. TXEN transitions synchronously with respect to REF_CLK. Transmit Data[1:0] (TXD[1:0]) When TXEN is asserted, TXD[1:0] are the data dibits presented by the MAC and accepted by the PHY for transmission. When TXEN is de-asserted, the MAC drives TXD[1:0] to either 00 for the idle state (non-EEE mode) or 01 for the LPI state (EEE mode). TXD[1:0] transitions synchronously with respect to REF_CLK. Carrier Sense / Receive Data Valid (CRS_DV) The PHY asserts CRS_DV when the receive medium is non-idle. It is asserted asynchronously when a carrier is detected. This happens when squelch is passed in 10Mbps mode, and when two non-contiguous 0s in 10 bits are detected in 100Mbps mode. Loss of carrier results in the de-assertion of CRS_DV. While carrier detection criteria are met, CRS_DV remains asserted continuously from the first recovered dibit of the frame through the final recovered dibit. It is negated before the first REF_CLK that follows the final dibit. The data on RXD[1:0] is considered valid after CRS_DV is asserted. However, because the assertion of CRS_DV is asynchronous relative to REF_CLK, the data on RXD[1:0] is 00 until receive signals are properly decoded. Receive Data[1:0] (RXD[1:0]) For each clock period in which CRS_DV is asserted, RXD[1:0] transfers a dibit of recovered data from the PHY. When CRS_DV is de-asserted, the PHY drives RXD[1:0] to either 00 for the idle state (non-EEE mode) or 01 for the LPI state (EEE mode). RXD[1:0] transitions synchronously with respect to REF_CLK. Receive Error (RXER) When CRS_DV is asserted, RXER is asserted for one or more REF_CLK periods to indicate that a symbol error (for example, a coding error that a PHY can detect that may otherwise be undetectable by the MAC sub-layer) is detected somewhere in the frame that is being transferred from the PHY to the MAC. RXER transitions synchronously with respect to REF_CLK. Collision Detection (COL) The MAC regenerates the COL signal of the MII from TXEN and CRS_DV. RMII Signal Diagram The KSZ8091RNB RMII pin connections to the MAC for 25MHz clock mode are shown in Figure 3. The connections for 50MHz clock mode are shown in Figure 4. August 31, 2015 25 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Figure 3. KSZ8091RNB RMII Interface (25MHz Clock Mode) Figure 4. KSZ8091RNB RMII Interface (50MHz Clock Mode) August 31, 2015 26 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Back-to-Back Mode – 100Mbps Copper Repeater Two KSZ8091MNX/RNB devices can be connected back-to-back to form a 100Base-TX copper repeater. Figure 5. KSZ8091MNX/RNB to KSZ8091MNX/RNB Back-to-Back Copper Repeater MII Back-to-Back Mode (KSZ8091MNX Only) In MII back-to-back mode, a KSZ8091MNX interfaces with another KSZ8091MNX to provide a complete 100Mbps copper repeater solution. The KSZ8091MNX devices are configured to MII back-to-back mode after power-up or reset with the following: • Strapping pin CONFIG[2:0] (pins 18, 29, 28) set to 110 • A common 25MHz reference clock connected to XI (pin 9) of both KSZ8091MNX devices • MII signals connected as shown in Table 3 Table 3. MII Signal Connection for MII Back-to-Back Mode (100Base-TX Copper Repeater) KSZ8091MNX (100Base-TX copper) [Device 1] KSZ8091MNX (100Base-TX copper) [Device 2] Pin Name Pin Number Pin Type Pin Name Pin Number Pin Type RXC 19 Output TXC 22 Input RXDV 18 Output TXEN 23 Input RXD3 13 Output TXD3 27 Input RXD2 14 Output TXD2 26 Input RXD1 15 Output TXD1 25 Input RXD0 16 Output TXD0 24 Input TXC 22 Input RXC 19 Output TXEN 23 Input RXDV 18 Output TXD3 27 Input RXD3 13 Output TXD2 26 Input RXD2 14 Output TXD1 25 Input RXD1 15 Output TXD0 24 Input RXD0 16 Output August 31, 2015 27 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB RMII Back-to-Back Mode (KSZ8091RNB Only) In RMII back-to-back mode, a KSZ8091RNB interfaces with another KSZ8091RNB to provide a complete 100Mbps copper repeater solution. The KSZ8091RNB devices are configured to RMII back-to-back mode after power-up or reset with the following: • Strapping pin CONFIG[2:0] (pins 18, 29, 28) set to 101 • A common 50MHz reference clock connected to XI (pin 9) of both KSZ8091RNB devices • RMII signals connected as shown in Table 4 Table 4. RMII Signal Connection for RMII Back-to-Back Mode (100Base-TX Copper Repeater) KSZ8091RNB (100Base-TX copper) [Device 1] KSZ8091RNB (100Base-TX copper) [Device 2] Pin Name Pin Number Pin Type Pin Name Pin Number Pin Type CRSDV 18 Output TXEN 23 Input RXD1 15 Output TXD1 25 Input RXD0 16 Output TXD0 24 Input TXEN 23 Input CRSDV 18 Output TXD1 25 Input RXD1 15 Output TXD0 24 Input RXD0 16 Output August 31, 2015 28 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MII Management (MIIM) Interface The KSZ8091MNX/RNB supports the IEEE 802.3 MII management interface, also known as the Management Data Input/Output (MDIO) interface. This interface allows an upper-layer device, such as a MAC processor, to monitor and control the state of the KSZ8091MNX/RNB. An external device with MIIM capability is used to read the PHY status and/or configure the PHY settings. More details about the MIIM interface can be found in Clause 22.2.4 of the IEEE 802.3 Specification. The MIIM interface consists of the following: • A physical connection that incorporates the clock line (MDC) and the data line (MDIO). • A specific protocol that operates across the physical connection mentioned earlier, which allows the external controller to communicate with one or more PHY devices. • A 32-register address space for direct access to IEEE-defined registers and vendor-specific registers, and for indirect access to MMD addresses and registers. See the “Register Map” section. As the default, the KSZ8091MNX/RNB supports unique PHY addresses 1 to 7, and broadcast PHY address 0. The latter is defined in the IEEE 802.3 Specification, and can be used to read/write to a single KSZ8091MNX/RNB device, or write to multiple KSZ8091MNX/RNB devices simultaneously. PHY address 0 can optionally be disabled as the broadcast address by either hardware pin strapping (B-CAST_OFF, pin 19) or software (Register 16h, bit [9]), and assigned as a unique PHY address. The PHYAD[2:0] strapping pins are used to assign a unique PHY address between 0 and 7 to each KSZ8091MNX/RNB device. The MIIM interface can operates up to a maximum clock speed of 10MHz MAC clock. Table 5 shows the MII management frame format for the KSZ8091MNX/RNB. Table 5. MII Management Frame Format for the KSZ8091MNX/RNB Preamble Start of Frame Read/Write OP Code PHY Address Bits [4:0] REG Address Bits [4:0] TA Data Bits [15:0] Idle Read 32 1’s 01 10 00AAA RRRRR Z0 DDDDDDDD_DDDDDDDD Z Write 32 1’s 01 01 00AAA RRRRR 10 DDDDDDDD_DDDDDDDD Z Interrupt (INTRP) INTRP (pin 21) is an optional interrupt signal that is used to inform the external controller that there has been a status update to the KSZ8091MNX/RNB PHY Register. Bits [15:8] of Register 1Bh are the interrupt control bits to enable and disable the conditions for asserting the INTRP signal. Bits [7:0] of Register 1Bh are the interrupt status bits to indicate which interrupt conditions have occurred. The interrupt status bits are cleared after reading Register 1Bh. Bit [9] of Register 1Fh sets the interrupt level to active high or active low. The default is active low. The MII management bus option gives the MAC processor complete access to the KSZ8091MNX/RNB control and status registers. Additionally, an interrupt pin eliminates the need for the processor to poll the PHY for status change. August 31, 2015 29 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB HP Auto MDI/MDI-X HP Auto MDI/MDI-X configuration eliminates the need to decide whether to use a straight cable or a crossover cable between the KSZ8091MNX/RNB and its link partner. This feature allows the KSZ8091MNX/RNB to use either type of cable to connect with a link partner that is in either MDI or MDI-X mode. The auto-sense function detects transmit and receive pairs from the link partner and assigns transmit and receive pairs to the KSZ8091MNX/RNB accordingly. HP Auto MDI/MDI-X is enabled by default. It is disabled by writing a ‘1’ to Register 1Fh, bit [13]. MDI and MDI-X mode is selected by Register 1Fh, bit [14] if HP Auto MDI/MDI-X is disabled. An isolation transformer with symmetrical transmit and receive data paths is recommended to support Auto MDI/MDI-X. Table 6 shows how the IEEE 802.3 Standard defines MDI and MDI-X. Table 6. MDI/MDI-X Pin Definition MDI MDI-X RJ-45 Pin Signal RJ-45 Pin Signal 1 TX+ 1 RX+ 2 TX− 2 RX− 3 RX+ 3 TX+ 6 RX− 6 TX− Straight Cable A straight cable connects an MDI device to an MDI-X device, or an MDI-X device to an MDI device. Figure 6 shows a typical straight cable connection between a NIC card (MDI device) and a switch or hub (MDI-X device). Figure 6. Typical Straight Cable Connection August 31, 2015 30 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Crossover Cable A crossover cable connects an MDI device to another MDI device, or an MDI-X device to another MDI-X device. Figure 7 shows a typical crossover cable connection between two switches or hubs (two MDI-X devices). Figure 7. Typical Crossover Cable Connection August 31, 2015 31 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Loopback Mode The KSZ8091MNX/RNB supports the following loopback operations to verify analog and/or digital data paths. • Local (digital) loopback • Remote (analog) loopback Local (Digital) Loopback This loopback mode checks the MII/RMII transmit and receive data paths between the KSZ8091MNX/RNB and the external MAC, and is supported for both speeds (10/100Mbps) at full-duplex. The loopback data path is shown in Figure 8. 1. The MII/RMII MAC transmits frames to the KSZ8091MNX/RNB. 2. Frames are wrapped around inside the KSZ8091MNX/RNB. 3. The KSZ8091MNX/RNB transmits frames back to the MII/RMII MAC. 4. Except the frames back to the RMII MAC, the transmit frames also go out from the copper port. Figure 8. Local (Digital) Loopback The following programming action and register settings are used for local loopback mode. For 10/100Mbps loopback, Set Register 0h, • Bit [14] = 1 // Enable local loopback mode • Bit [13] = 0/1 // Select 10Mbps/100Mbps speed • Bit [12] = 0 // Disable auto-negotiation • Bit [8] = 1 // Select full-duplex mode August 31, 2015 32 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Remote (Analog) Loopback This loopback mode checks the line (differential pairs, transformer, RJ-45 connector, Ethernet cable) transmit and receive data paths between the KSZ8091MNX/RNB and its link partner, and is supported for 100Base-TX full-duplex mode only. The loopback data path is shown in Figure 9. 1. The Fast Ethernet (100Base-TX) PHY link partner transmits frames to the KSZ8091MNX/RNB. 2. Frames are wrapped around inside the KSZ8091MNX/RNB. 3. The KSZ8091MNX/RNB transmits frames back to the Fast Ethernet (100Base-TX) PHY link partner. Figure 9. Remote (Analog) Loopback The following programming steps and register settings are used for remote loopback mode. 1. Set Register 0h, − Bits [13] = 1 // Select 100Mbps speed − Bit [12] = 0 // Disable auto-negotiation − Bit [8] = 1 // Select full-duplex mode Or just auto-negotiate and link up with the link partner at 100Base-TX full-duplex mode. 2. Set Register 1Fh, − Bit [2] = 1 August 31, 2015 // Enable remote loopback mode 33 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB LinkMD® Cable Diagnostic The LinkMD function uses time-domain reflectometry (TDR) to analyze the cabling plant for common cabling problems. These include open circuits, short circuits, and impedance mismatches. LinkMD works by sending a pulse of known amplitude and duration down the MDI or MDI-X pair, then analyzing the shape of the reflected signal to determine the type of fault. The time duration for the reflected signal to return provides the approximate distance to the cabling fault. The LinkMD function processes this TDR information and presents it as a numerical value that can be translated to a cable distance. LinkMD is initiated by accessing register 1Dh, the LinkMD Cable Diagnostic register, in conjunction with Register 1Fh, the PHY Control 2 Register. The latter register is used to disable Auto MDI/MDI-X and to select either MDI or MDI-X as the cable differential pair for testing. Usage The following is a sample procedure for using LinkMD with Registers 1Dh and 1Fh: 3. Disable auto MDI/MDI-X by writing a ‘1’ to Register 1Fh, bit [13]. 4. Start cable diagnostic test by writing a ‘1’ to Register 1Dh, bit [15]. This enable bit is self-clearing. 5. Wait (poll) for Register 1Dh, bit [15] to return a ‘0’, and indicating cable diagnostic test is completed. 6. Read cable diagnostic test results in Register 1Dh, bits [14:13]. The results are as follows: 00 = normal condition (valid test) 01 = open condition detected in cable (valid test) 10 = short condition detected in cable (valid test) 11 = cable diagnostic test failed (invalid test) The ‘11’ case, invalid test, occurs when the device is unable to shut down the link partner. In this instance, the test is not run, since it would be impossible for the device to determine if the detected signal is a reflection of the signal generated or a signal from another source. 7. Get distance to fault by concatenating Register 1Dh, bits [8:0] and multiplying the result by a constant of 0.38. The distance to the cable fault can be determined by the following formula: D (distance to cable fault) = 0.38 x (Register 1Dh, bits [8:0]) D (distance to cable fault) is expressed in meters. Concatenated value of Registers 1Dh bits [8:0] should be converted to decimal before multiplying by 0.38. The constant (0.38) may be calibrated for different cabling conditions, including cables with a velocity of propagation that varies significantly from the norm. August 31, 2015 34 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB NAND Tree Support The KSZ8091MNX/RNB provides parametric NAND tree support for fault detection between chip I/Os and board. The NAND tree is a chain of nested NAND gates in which each KSZ8091MNX/RNB digital I/O (NAND tree input) pin is an input to one NAND gate along the chain. At the end of the chain, the CRS/CONFIG1 pin provides the output for the nested NAND gates. The NAND tree test process includes: • Enabling NAND tree mode • Pulling all NAND tree input pins high • Driving each NAND tree input pin low, sequentially, according to the NAND tree pin order • Checking the NAND tree output to make sure there is a toggle high-to-low or low-to-high for each NAND tree input driven low Table 7 and Table 8 list the NAND tree pin orders for KSZ8091MNX and KSZ8091RNB, respectively. Table 7. NAND Tree Test Pin Order for KSZ8091MNX Pin Number Pin Name NAND Tree Description 11 MDIO Input 12 MDC Input 13 RXD3 Input 14 RXD2 Input 15 RXD1 Input 16 RXD0 Input 18 RXDV Input 19 RXC Input 20 RXER Input 21 INTRP Input 22 TXC Input 23 TXEN Input 24 TXD0 Input 25 TXD1 Input 26 TXD2 Input 27 TXD3 Input 30 LED0 Input 28 COL Input 29 CRS Output August 31, 2015 35 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Table 8. NAND Tree Test Pin Order for KSZ8091RNB Pin Number Pin Name NAND Tree Description 11 MDIO Input 12 MDC Input 13 PHYAD0 Input 14 PHYAD1 Input 15 RXD1 Input 16 RXD0 Input 18 CRS_DV Input 19 REF_CLK Input 20 RXER Input 21 INTRP Input 22 PME_EN Input 23 TXEN Input 24 TXD0 Input 25 TXD1 Input 30 LED0 Input 31 LED1 Input 28 CONFIG0 Input 29 CONFIG1 Output NAND Tree I/O Testing Use the following procedure to check for faults on the KSZ8091MNX/RNB digital I/O pin connections to the board: 1. Enable NAND tree mode using either hardware (NAND_Tree#, pin 21) or software (Register 16h, bit [5]). 2. Use board logic to drive all KSZ8091MNX/RNB NAND tree input pins high. 3. Use board logic to drive each NAND tree input pin, in KSZ8091MNX/RNB NAND tree pin order, as follows: a. Toggle the first pin (MDIO) from high to low, and verify that the CRS/CONFIG1 pin switches from high to low to indicate that the first pin is connected properly. b. Leave the first pin (MDIO) low. c. Toggle the second pin (MDC) from high to low, and verify that the CRS/CONFIG1 pin switches from low to high to indicate that the second pin is connected properly. d. Leave the first pin (MDIO) and the second pin (MDC) low. e. Toggle the third pin (RXD3/PHYAD0)) from high to low, and verify that the CRS/CONFIG1 pin switches from high to low to indicate that the third pin is connected properly. f. Continue with this sequence until all KSZ8091MNX/RNB NAND tree input pins have been toggled. Each KSZ8091MNX/RNB NAND tree input pin must cause the CRS/CONFIG1 output pin to toggle high-to-low or low-tohigh to indicate a good connection. If the CRS/CONFIG1 pin fails to toggle when the KSZ8091MNX/RNB input pin toggles from high to low, the input pin has a fault. August 31, 2015 36 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Power Management The KSZ8091MNX/RNB incorporates a number of power-management modes and features that provide methods to consume less energy. These are discussed in the following sections. Power-Saving Mode Power-saving mode is used to reduce the transceiver power consumption when the cable is unplugged. It is enabled by writing a ‘1’ to Register 1Fh, bit [10], and is in effect when auto-negotiation mode is enabled and the cable is disconnected (no link). In this mode, the KSZ8091MNX/RNB shuts down all transceiver blocks, except for the transmitter, energy detect, and PLL circuits. By default, power-saving mode is disabled after power-up. Energy-Detect Power-Down Mode Energy-detect power-down (EDPD) mode is used to further reduce transceiver power consumption when the cable is unplugged. It is enabled by writing a ‘0’ to Register 18h, bit [11], and is in effect when auto-negotiation mode is enabled and the cable is disconnected (no link). EDPD mode works with the PLL off (set by writing a ‘1’ to Register 10h, bit [4] to automatically turn the PLL off in EDPD mode) to turn off all KSZ8091MNX/RNB transceiver blocks except the transmitter and energy-detect circuits. Power can be reduced further by extending the time interval between transmissions of link pulses to check for the presence of a link partner. The periodic transmission of link pulses is needed to ensure the KSZ8091MNX/RNB and its link partner, when operating in the same low-power state and with Auto MDI/MDI-X disabled, can wake up when the cable is connected between them. By default, energy-detect power-down mode is disabled after power-up. Power-Down Mode Power-down mode is used to power down the KSZ8091MNX/RNB device when it is not in use after power-up. It is enabled by writing a ‘1’ to Register 0h, bit [11]. In this mode, the KSZ8091MNX/RNB disables all internal functions except the MII management interface. The KSZ8091MNX/RNB exits (disables) power-down mode after Register 0h, bit [11] is set back to ‘0’. Slow-Oscillator Mode Slow-oscillator mode is used to disconnect the input reference crystal/clock on XI (pin 9) and select the on-chip slow oscillator when the KSZ8091MNX/RNB device is not in use after power-up. It is enabled by writing a ‘1’ to Register 11h, bit [5]. Slow-oscillator mode works in conjunction with power-down mode to put the KSZ8091MNX/RNB device in the lowest power state, with all internal functions disabled except the MII management interface. To properly exit this mode and return to normal PHY operation, use the following programming sequence: 1. Disable slow-oscillator mode by writing a ‘0’ to Register 11h, bit [5]. 2. Disable power-down mode by writing a ‘0’ to Register 0h, bit [11]. 3. Initiate software reset by writing a ‘1’ to Register 0h, bit [15]. August 31, 2015 37 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Energy Efficient Ethernet (EEE) The KSZ8091MNX implements Energy Efficient Ethernet (EEE) for the Media Independent Interface (MII) as described in IEEE Standard 802.3az. The Standard is defined around an EEE-compliant MAC on the host side and an EEE-compliant link partner on the line side that support special signaling associated with EEE. EEE saves power by keeping the AC signal on the copper Ethernet cable at approximately 0V peak-to-peak as often as possible during periods of no traffic activity, while maintaining the link-up status. This is referred to as low-power idle (LPI) mode or state. Similarly, the KSZ8091RNB implements EEE for the Reduced Media Independent Interface (RMII) as described in IEEE Standard 802.3az for line signaling by the two differential pairs (analog side) and according to the multisource agreement (MSA) of collaborating Fast Ethernet chip vendors for the RMII (digital side). This agreement is based on the IEEE Standard’s EEE implementation for MII (100Mbps). During LPI mode, the copper link responds automatically when it receives traffic and resumes normal PHY operation immediately, without blockage of traffic or loss of packet. This involves exiting LPI mode and returning to normal 100Mbps operating mode. Wake-up time is <30µs for 100Base-TX. The LPI state is controlled independently for transmit and receive paths, allowing the LPI state to be active (enabled) for: • Transmit cable path only • Receive cable path only • Both transmit and receive cable paths The KSZ8091MNX/RNB has the EEE function disabled as the power-up default setting. To enable the EEE function for 100Mbps mode, use the following programming sequence: 1. Enable 100Mbps EEE mode advertisement by writing a ‘1’ to MMD address 7h, Register 3Ch, bit [1]. 2. Restart auto-negotiation by writing a ‘1’ to standard Register 0h, bit [9]. For standard (non-EEE) 10Base-T mode, normal link pulses (NLPs) with long periods of no AC signal transmission are used to maintain the link during the idle period when there is no traffic activity. To save more power, the KSZ8091MNX/RNB provides the option to enable 10Base-Te mode, which saves additional power by reducing the transmitted signal amplitude from 2.5V to 1.75V. To enable 10Base-Te mode, write a ‘1’ to standard Register 13h, bit [4]. During LPI mode, refresh transmissions are used to maintain the link; power savings occur in quiet periods. Approximately every 20 to 22 milliseconds, a refresh transmission of 200 to 220 microseconds is sent to the link partner. The refresh transmissions and quiet periods are shown in Figure 10. Figure 10. LPI Mode (Refresh Transmissions and Quiet Periods) August 31, 2015 38 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Transmit Direction Control (MAC-to-PHY) The KSZ8091MNX enters LPI mode for the transmit direction when its attached EEE-compliant MII MAC de-asserts TXEN, asserts TXER, and sets TXD[3:0] to 0001. The KSZ8091MNX remains in the LPI transmit state while the MAC maintains the states of these signals. When the MAC changes any of the TXEN, TXER, or TX data signals from their LPI state values, the KSZ8091MNX exits the LPI transmit state. The TXC clock is not stopped, because it is sourced from the PHY and is used by the MAC for MII transmit. Figure 11 shows the LPI transition for MII (100Mbps) transmit. Figure 11. LPI Transition – MII (100Mbps) Transmit Similarly, the KSZ8091RNB enters LPI mode for the transmit direction when its attached EEE-compliant RMII MAC deasserts TXEN and sets TXD [1:0] to 01. The KSZ8091RNB remains in the LPI transmit state while the RMII MAC maintains the states of these signals. When the RMII MAC changes any of the TXEN or TX data signals from their LPI state values, the KSZ8091RNB exits the LPI transmit state. Figure 12 shows the LPI transition for RMII (100Mbps) transmit. Figure 12. LPI Transition – RMII (100Mbps) Transmit August 31, 2015 39 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Receive Direction Control (PHY-to-MAC) The KSZ8091MNX enters LPI mode for the receive direction when it receives the /P/ code bit pattern (Sleep/Refresh) from its EEE-compliant link partner. It then de-asserts RXDV, asserts RXER, and drives RXD[3:0] to 0001. The KSZ8091MNX remains in the LPI receive state while it continues to receive the refresh from its link partner, so it will continue to maintain and drive the LPI output states for the MII receive signals to inform the attached EEE-compliant MII MAC that it is in the LPI receive state. When the KSZ8091MNX receives a non /P/ code bit pattern (non-refresh), it exits the LPI receive state and sets the RXDV, RXER, and RX data signals to set a normal frame or normal idle. The KSZ8091MNX stops the RXC clock output to the MAC after nine or more RXC clock cycles have occurred in the LPI receive state, to save more power. By default, RXC clock stoppage is enabled. It is disabled by writing a ‘0’ to MMD address 3h, Register 0h, Bit [10]. Figure 13 shows the LPI transition for MII (100Mbps) receive. Figure 13. LPI Transition – MII (100Mbps) Receive Similarly, the KSZ8091RNB enters LPI mode for the receive direction when it receives the /P/ code bit pattern (Sleep/Refresh) from its EEE-compliant link partner. It then de-asserts CRS_DV and drives RXD[1:0] to 01. The KSZ8091RNB remains in the LPI receive state while it continues to receive the refresh from its link partner, so it will continue to maintain and drive the LPI output states for the RMII receive signals to inform the attached EEE-compliant RMII MAC that it is in the LPI receive state. When the KSZ8091RNB receives a non /P/ code bit pattern (non-refresh), it exits the LPI receive state and sets the CRS_DV and RX data signals to set a normal frame or normal idle. Figure 14 shows the LPI transition for RMII (100Mbps) receive. Figure 14. LPI Transition – RMII (100Mbps) Receive August 31, 2015 40 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Registers Associated with EEE The following registers are provided for EEE configuration and management: • Standard Register 13h - AFE Control 4 (to enable 10Base-Te mode) • MMD address 1h, Register 0h - PMA/PMD Control 1 (to enable LPI) • MMD address 1h, Register 1h - PMA/PMD Status 1 (for LPI status) • MMD address 3h, Register 0h - EEE PCS Control 1 (to stop RXC clock for KSZ8091MNX only) • MMD address 7h, Register 3Ch - EEE Advertisement • MMD address 7h, Register 3Dh - EEE Link Partner Advertisement August 31, 2015 41 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Wake-On-LAN Wake-On-LAN (WOL) is normally a MAC-based function to wake up a host system (for example, an Ethernet end device, such as a PC) that is in standby power mode. Wake-up is triggered by receiving and detecting a special packet (commonly referred to as the “magic packet”) that is sent by the remote link partner. The KSZ8091MNX/RNB can perform the same WOL function if the MAC address of its associated MAC device is entered into the KSZ8091MNX/RNB PHY registers for magic-packet detection. When the KSZ8091MNX/RNB detects the magic packet, it wakes up the host by driving its power management event (PME) output pin low. By default, the WOL function is disabled. It is enabled by setting the enabling bit and configuring the associated registers for the selected PME wake-up detection method. The KSZ8091MNX/RNB provides three methods to trigger a PME wake-up: • Magic-packet detection • Customized-packet detection • Link status change detection Magic-Packet Detection The magic packet’s frame format starts with 6 bytes of 0xFFh and is followed by 16 repetitions of the MAC address of its associated MAC device (local MAC device). When the magic packet is detected from its link partner, the KSZ8091MNX/RNB asserts its PME output pin low. The following MMD address 1Fh registers are provided for magic-packet detection: • Magic-packet detection is enabled by writing a ‘1’ to MMD address 1Fh, Register 0h, bit [6] • The MAC address (for the local MAC device) is written to and stored in MMD address 1Fh, Registers 19h – 1Bh The KSZ8091MNX/RNB does not generate the magic packet. The magic packet must be provided by the external system. August 31, 2015 42 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Customized-Packet Detection The customized packet has associated register/bit masks to select which byte, or bytes, of the first 64 bytes of the packet to use in the CRC calculation. After the KSZ8091MNX/RNB receives the packet from its link partner, the selected bytes for the received packet are used to calculate the CRC. The calculated CRC is compared to the expected CRC value that was previously written to and stored in the KSZ8091MNX/RNB PHY Registers. If there is a match, the KSZ8091MNX/RNB asserts its PME output pin low. Four customized packets are provided to support four types of wake-up scenarios. A dedicated set of registers is used to configure and enable each customized packet. The following MMD Registers are provided for customized-packet detection: • • • Each of the four customized packets is enabled via MMD address 1Fh, Register 0h, − Bit [2] // For customized packets, type 0 − Bit [3] // For customized packets, type 1 − Bit [4] // For customized packets, type 2 − Bit [5] // For customized packets, type 3 Masks to indicate which of the first 64-bytes to use in the CRC calculation are set in: − MMD address 1Fh, Registers 1h – 4h // For customized packets, type 0 − MMD address 1Fh, Registers 7h – Ah // For customized packets, type 1 − MMD address 1Fh, Registers Dh – 10h // For customized packets, type 2 − MMD address 1Fh, Registers 13h – 16h // For customized packets, type 3 32-bit expected CRCs are written to and stored in: − MMD address 1Fh, Registers 5h – 6h // For customized packets, type 0 − MMD address 1Fh, Registers Bh – Ch // For customized packets, type 1 − MMD address 1Fh, Registers 11h – 12h // For customized packets, type 2 − MMD address 1Fh, Registers 17h – 18h // For customized packets, type 3 Link Status Change Detection If link status change detection is enabled, the KSZ8091MNX/RNB asserts its PME output pin low whenever there is a link status change, using the following MMD address 1Fh register bits and their enabled (1) or disabled (0) settings: • MMD address 1Fh, Register 0h, bit [0] // For link-up detection • MMD address 1Fh, Register 0h, bit [1] // For link-down detection The PME output signal is available on either INTRP/PME_N2 (pin 21) or LED0/PME_N1 (pin 30), and is enabled using standard Register 16h, bit [15]. MMD address 1Fh, Register 0h, bits [15:14] defines and selects the output functions for pins 21 and 30. The PME output is active low and requires a 1kΩ pull-up to the VDDIO supply. When asserted, the PME output is cleared by disabling the register bit that enabled the PME trigger source (magic packet, customized packet, link status change). August 31, 2015 43 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Reference Circuit for Power and Ground Connections The KSZ8091MNX/RNB is a single 3.3V supply device with a built-in regulator to supply the 1.2V core. The power and ground connections are shown in Figure 15 and Table 9 for 3.3V VDDIO. Figure 15. KSZ8091MNX/RNB Power and Ground Connections Table 9. KSZ8091MNX/RNB Power Pin Description Power Pin VDD_1.2 VDDA_3.3 VDDIO August 31, 2015 Pin Number Description 2 Decouple with 2.2µF and 0.1µF capacitors to ground. 3 Connect to board’s 3.3V supply through a ferrite bead. Decouple with 22µF and 0.1µF capacitors to ground. 17 Connect to board’s 3.3V supply for 3.3V VDDIO. Decouple with 22µF and 0.1µF capacitors to ground. 44 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Typical Current/Power Consumption Table 10 through Table 12 show typical values for current consumption by the transceiver (VDDA_3.3) and digital I/O (VDDIO) power pins, and typical values for power consumption by the KSZ8091MNX/RNB device for the indicated nominal operating voltages. These current and power consumption values include the transmit driver current and on-chip regulator current for the 1.2V core. Transceiver (3.3V), Digital I/Os (3.3V) Table 10. Typical Current/Power Consumption (VDDA_3.3 = 3.3V, VDDIO = 3.3V) 3.3V Transceiver (VDDA_3.3) 3.3V Digital I/Os (VDDIO) Total Chip Power mA mA mW 100Base-TX Link-up (no traffic) 34 12 152 100Base-TX Full-duplex @ 100% utilization 34 13 155 10Base-T Link-up (no traffic) 14 11 82.5 10Base-T Full-duplex @ 100% utilization 30 11 135 EEE 100Mbps Link-up mode (transmit and receive in LPI state with no traffic) 13 10 75.9 Power-saving mode (Reg. 1Fh, bit [10] = 1) 13 10 75.9 EDPD mode (Reg. 18h, bit [11] = 0) 10 10 66.0 EDPD mode (Reg. 18h, bit [11] = 0) and PLL off (Reg. 10h, bit [4] = 1) 3.77 1.54 17.5 Software power-down mode (Reg. 0h, bit [11] =1) 2.59 1.51 13.5 Software power-down mode (Reg. 0h, bit [11] =1) and slow-oscillator mode (Reg. 11h, bit [5] =1) 1.36 0.45 5.97 Condition Transceiver (3.3V), Digital I/Os (2.5V) Table 11. Typical Current/Power Consumption (VDDA_3.3 = 3.3V, VDDIO = 2.5V) 3.3V Transceiver (VDDA_3.3) 2.5V Digital I/Os (VDDIO) Total Chip Power mA mA mW 100Base-TX Link-up (no traffic) 34 11 140 100Base-TX Full-duplex @ 100% utilization 34 12 142 10Base-T Link-up (no traffic) 15 10 74.5 10Base-T Full-duplex @ 100% utilization 27 10 114 EEE 100Mbps Link-up mode (transmit and receive in LPI state with no traffic) 13 10 67.9 Power-saving mode (Reg. 1Fh, bit [10] = 1) 13 10 67.9 EDPD mode (Reg. 18h, bit [11] = 0) 11 10 61.3 EDPD mode (Reg. 18h, bit [11] = 0) and PLL off (Reg. 10h, bit [4] = 1) 3.55 1.35 15.1 Software power-down mode (Reg. 0h, bit [11] =1) 2.29 1.34 10.9 Software power-down mode (Reg. 0h, bit [11] =1) and slow-oscillator mode (Reg. 11h, bit [5] =1) 1.15 0.29 4.52 Condition August 31, 2015 45 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Transceiver (3.3V), Digital I/Os (1.8V) Table 12. Typical Current/Power Consumption (VDDA_3.3 = 3.3V, VDDIO = 1.8V) 3.3V Transceiver (VDDA_3.3) 1.8V Digital I/Os (VDDIO) Total Chip Power mA mA mW 100Base-TX Link-up (no traffic) 34 11 132 100Base-TX Full-duplex @ 100% utilization 34 12 134 10Base-T Link-up (no traffic) 15 9.0 65.7 10Base-T Full-duplex @ 100% utilization 27 9.0 105 EEE 100Mbps Link-up mode (transmit and receive in LPI state with no traffic) 13 9.0 59.1 Power-saving mode (Reg. 1Fh, bit [10] = 1) 13 9.0 59.1 EDPD mode (Reg. 18h, bit [11] = 0) 11 9.0 52.5 EDPD mode (Reg. 18h, bit [11] = 0) and PLL off (Reg. 10h, bit [4] = 1) 4.05 1.21 15.5 Software power-down mode (Reg. 0h, bit [11] =1) 2.79 1.21 11.4 Software power-down mode (Reg. 0h, bit [11] =1) and slow-oscillator mode (Reg. 11h, bit [5] =1) 1.65 0.19 5.79 Condition August 31, 2015 46 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Register Map The register space within the KSZ8091MNX/RNB consists of two distinct areas. • Standard registers • MDIO manageable device (MMD) registers // Indirect register access // Direct register access The KSZ8091MNX/RNB supports the following standard registers. Table 13. Standard Registers Supported by KSZ8091MNX/RNB Register Number (Hex) Description IEEE-Defined Registers 0h Basic Control 1h Basic Status 2h PHY Identifier 1 3h PHY Identifier 2 4h Auto-Negotiation Advertisement 5h Auto-Negotiation Link Partner Ability 6h Auto-Negotiation Expansion 7h Auto-Negotiation Next Page 8h Auto-Negotiation Link Partner Next Page Ability 9h – Ch Reserved Dh MMD Access – Control Eh MMD Access – Register/Data Fh Reserved Vendor-Specific Registers 10h Digital Reserved Control 11h AFE Control 1 12h Reserved 13h AFE Control 4 14h Reserved 15h RXER Counter 16h Operation Mode Strap Override 17h Operation Mode Strap Status 18h Expanded Control 19h – 1Ah Reserved 1Bh Interrupt Control/Status 1Ch Reserved 1Dh LinkMD Cable Diagnostic 1Eh PHY Control 1 1Fh PHY Control 2 August 31, 2015 47 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB The KSZ8091MNX/RNB supports the following MMD device addresses and their associated register addresses, which make up the indirect MMD registers. Table 14. MMD Registers Supported by KSZ8091MNX/RNB Device Address (Hex) 1h 3h 7h 1Fh August 31, 2015 Register Address (Hex) Description 0h PMA/PMD Control 1 1h PMA/PMD Status 1 0h EEE PCS Control 1 3Ch EEE Advertisement 3Dh EEE Link Partner Advertisement 0h Wake-On-LAN – Control 1h Wake-On-LAN – Customized Packet, Type 0, Mask 0 2h Wake-On-LAN – Customized Packet, Type 0, Mask 1 3h Wake-On-LAN – Customized Packet, Type 0, Mask 2 4h Wake-On-LAN – Customized Packet, Type 0, Mask 3 5h Wake-On-LAN – Customized Packet, Type 0, Expected CRC 0 6h Wake-On-LAN – Customized Packet, Type 0, Expected CRC 1 7h Wake-On-LAN – Customized Packet, Type 1, Mask 0 8h Wake-On-LAN – Customized Packet, Type 1, Mask 1 9h Wake-On-LAN – Customized Packet, Type 1, Mask 2 Ah Wake-On-LAN – Customized Packet, Type 1, Mask 3 Bh Wake-On-LAN – Customized Packet, Type 1, Expected CRC 0 Ch Wake-On-LAN – Customized Packet, Type 1, Expected CRC 1 Dh Wake-On-LAN – Customized Packet, Type 2, Mask 0 Eh Wake-On-LAN – Customized Packet, Type 2, Mask 1 Fh Wake-On-LAN – Customized Packet, Type 2, Mask 2 10h Wake-On-LAN – Customized Packet, Type 2, Mask 3 11h Wake-On-LAN – Customized Packet, Type 2, Expected CRC 0 12h Wake-On-LAN – Customized Packet, Type 2, Expected CRC 1 13h Wake-On-LAN – Customized Packet, Type 3, Mask 0 14h Wake-On-LAN – Customized Packet, Type 3, Mask 1 15h Wake-On-LAN – Customized Packet, Type 3, Mask 2 16h Wake-On-LAN – Customized Packet, Type 3, Mask 3 17h Wake-On-LAN – Customized Packet, Type 3, Expected CRC 0 18h Wake-On-LAN – Customized Packet, Type 3, Expected CRC 1 19h Wake-On-LAN – Magic Packet, MAC-DA-0 1Ah Wake-On-LAN – Magic Packet, MAC-DA-1 1Bh Wake-On-LAN – Magic Packet, MAC-DA-2 48 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Standard Registers Standard registers provide direct read/write access to a 32-register address space, as defined in Clause 22 of the IEEE 802.3 Specification. Within this address space, the first 16 registers (Registers 0h to Fh) are defined according to the IEEE specification, while the remaining 16 registers (Registers 10h to 1Fh) are defined specific to the PHY vendor. IEEE-Defined Registers – Descriptions Address Name (9 ) Description Mode Default 1 = Software reset RW/SC 0 RW 0 RW Set by the SPEED strapping pin (KSZ8091RNB only). Register 0h – Basic Control 0.15 Reset 0 = Normal operation This bit is self-cleared after a ‘1’ is written to it. 0.14 Loopback 1 = Loopback mode 0 = Normal operation 0.13 Speed Select 1 = 100Mbps 0 = 10Mbps See the “Strapping Options – KSZ8091RNB” section for details. This bit is ignored if auto-negotiation is enabled (register 0.12 = 1). 0.12 AutoNegotiation Enable 1 = Enable auto-negotiation process RW 0 = Disable auto-negotiation process See the “Strapping Options – KSZ8091MNX” section for details. If enabled, the auto-negotiation result overrides the settings in Registers 0.13 and 0.8. 0.11 Power-Down 1 = Power-down mode Set by the NWAYEN strapping pin. RW 0 RW Set by the ISO strapping pin. 0 = Normal operation If software reset (Register 0.15) is used to exit power-down mode (Register 0.11 = 1), two software reset writes (Register 0.15 = 1) are required. The first write clears power-down mode; the second write resets the chip and relatches the pin strapping pin values. 0.10 Isolate 1 = Electrical isolation of PHY from MII/RMII 0 = Normal operation 0.9 Restart AutoNegotiation See the “Strapping Options – KSZ8091MNX” section for details. 1 = Restart auto-negotiation process RW/SC 0 RW The inverse of the DUPLEX strapping pin value. 0 = Normal operation. This bit is self-cleared after a ‘1’ is written to it. 0.8 Duplex Mode 1 = Full-duplex 0 = Half-duplex See the “Strapping Options – KSZ8091MNX” section for details. 0.7 Collision Test 1 = Enable COL test RW 0 Reserved RO 000_0000 1 = T4 capable RO 0 0 = Disable COL test 0.6:0 Reserved Register 1h – Basic Status 1.15 100Base-T4 0 = Not T4 capable August 31, 2015 49 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (9 ) Address Name Description Mode 1.14 100Base-TX Full-Duplex 1 = Capable of 100Mbps full-duplex RO 1 RO 1 RO 1 RO 1 1.13 Default 0 = Not capable of 100Mbps full-duplex 100Base-TX Half-Duplex 1 = Capable of 100Mbps half-duplex 10Base-T Full-Duplex 1 = Capable of 10Mbps full-duplex 10Base-T Half-Duplex 1 = Capable of 10Mbps half-duplex 1.10:7 Reserved Reserved RO 000_0 1.6 No Preamble 1 = Preamble suppression RO 1 RO 0 RO/LH 0 RO 1 RO/LL 0 RO/LH 0 1 = Supports extended capability registers RO 1 Assigned to the 3rd through 18th bits of the Organizationally Unique Identifier (OUI). KENDIN Communication’s OUI is 0010A1 (hex). RO 0022h 1.12 1.11 0 = Not capable of 100Mbps half-duplex 0 = Not capable of 10Mbps full-duplex 0 = Not capable of 10Mbps half-duplex 0 = Normal preamble 1.5 1.4 AutoNegotiation Complete Remote Fault 1 = Auto-negotiation process completed 0 = Auto-negotiation process not completed 1 = Remote fault 0 = No remote fault 1.3 1.2 AutoNegotiation Ability 1 = Can perform auto-negotiation Link Status 1 = Link is up 0 = Cannot perform auto-negotiation 0 = Link is down 1.1 Jabber Detect 1 = Jabber detected 0 = Jabber not detected (default is low) 1.0 Extended Capability Register 2h – PHY Identifier 1 2.15:0 PHY ID Number Register 3h – PHY Identifier 2 3.15:10 PHY ID Number Assigned to the 19th through 24th bits of the Organizationally Unique Identifier (OUI). KENDIN Communication’s OUI is 0010A1 (hex). RO 0001_01 3.9:4 Model Number Six-bit manufacturer’s model number RO 01_0110 3.3:0 Revision Number Four-bit manufacturer’s revision number RO Indicates silicon revision RW 0 Register 4h – Auto-Negotiation Advertisement 4.15 Next Page 1 = Next page capable 0 = No next page capability 4.14 Reserved Reserved RO 0 4.13 Remote Fault 1 = Remote fault supported RW 0 0 = No remote fault August 31, 2015 50 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (9 ) Address Name Description Mode Default 4.12 Reserved Reserved RO 0 4.11:10 Pause [00] = No pause RW 00 RO 0 RW Set by the SPEED strapping pin (KSZ8091RNB only). [10] = Asymmetric pause [01] = Symmetric pause [11] = Asymmetric and symmetric pause 4.9 100Base-T4 1 = T4 capable 0 = No T4 capability 4.8 100Base-TX Full-Duplex 1 = 100Mbps full-duplex capable 0 = No 100Mbps full-duplex capability See the “Strapping Options – KSZ8091RNB” section for details. 4.7 100Base-TX Half-Duplex 1 = 100Mbps half-duplex capable RW 0 = No 100Mbps half-duplex capability Set by the SPEED strapping pin (KSZ8091RNB only). See the “Strapping Options – KSZ8091RNB” section for details. 4.6 4.5 4.4:0 10Base-T Full-Duplex 1 = 10Mbps full-duplex capable 10Base-T Half-Duplex 1 = 10Mbps half-duplex capable Selector Field [00001] = IEEE 802.3 RW 1 RW 1 RW 0_0001 RO 0 RO 0 RO 0 0 = No 10Mbps full-duplex capability 0 = No 10Mbps half-duplex capability Register 5h – Auto-Negotiation Link Partner Ability 5.15 Next Page 1 = Next page capable 0 = No next page capability 5.14 Acknowledge 1 = Link code word received from partner 0 = Link code word not yet received 5.13 Remote Fault 1 = Remote fault detected 0 = No remote fault 5.12 Reserved Reserved RO 0 5.11:10 Pause [00] = No pause RO 00 RO 0 RO 0 RO 0 RO 0 RO 0 [10] = Asymmetric pause [01] = Symmetric pause [11] = Asymmetric and symmetric pause 5.9 100Base-T4 1 = T4 capable 0 = No T4 capability 5.8 5.7 5.6 5.5 100Base-TX Full-Duplex 1 = 100Mbps full-duplex capable 0 = No 100Mbps full-duplex capability 100Base-TX Half-Duplex 1 = 100Mbps half-duplex capable 10Base-T Full-Duplex 1 = 10Mbps full-duplex capable 10Base-T Half-Duplex August 31, 2015 0 = No 100Mbps half-duplex capability 0 = No 10Mbps full-duplex capability 1 = 10Mbps half-duplex capable 0 = No 10Mbps half-duplex capability 51 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (9 ) Address Name Description Mode Default 5.4:0 Selector Field [00001] = IEEE 802.3 RO 0_0001 Register 6h – Auto-Negotiation Expansion 6.15:5 Reserved Reserved RO 0000_0000_000 6.4 Parallel Detection Fault 1 = Fault detected by parallel detection RO/LH 0 Link Partner Next Page Able 1 = Link partner has next page capability RO 0 RO 1 RO/LH 0 RO 0 RW 0 6.3 6.2 6.1 Next Page Able Page Received 0 = No fault detected by parallel detection 0 = Link partner does not have next page capability 1 = Local device has next page capability 0 = Local device does not have next page capability 1 = New page received 0 = New page not received yet 6.0 Link Partner AutoNegotiation Able 1 = Link partner has auto-negotiation capability 0 = Link partner does not have auto-negotiation capability Register 7h – Auto-Negotiation Next Page 7.15 Next Page 1 = Additional next pages will follow 0 = Last page 7.14 Reserved Reserved RO 0 7.13 Message Page 1 = Message page RW 1 RW 0 RO 0 RW 000_0000_0001 RO 0 RO 0 RO 0 RO 0 RO 0 RO 000_0000_0000 0 = Unformatted page 7.12 Acknowledge2 1 = Will comply with message 0 = Cannot comply with message 7.11 Toggle 1 = Previous value of the transmitted link code word equaled logic 1 0 = Logic 0 7.10:0 Message Field 11-bit wide field to encode 2048 messages Register 8h – Auto-Negotiation Link Partner Next Page Ability 8.15 Next Page 1 = Additional next pages will follow 0 = Last page 8.14 Acknowledge 1 = Successful receipt of link word 0 = No successful receipt of link word 8.13 Message Page 1 = Message page 0 = Unformatted page 8.12 Acknowledge2 1 = Can act on the information 0 = Cannot act on the information 8.11 Toggle 1 = Previous value of transmitted link code word equal to logic 0 0 = Previous value of transmitted link code word equal to logic 1 8.10:0 Message Field August 31, 2015 11-bit wide field to encode 2048 messages 52 Revision 1.2 Micrel, Inc. Address KSZ8091MNX/KSZ8091RNB Name Description Mode (9 ) Default Register Dh – MMD Access – Control D.15:14 MMD – Operation Mode For the selected MMD device address (bits [4:0] of this register), these two bits select one of the following register or data operations and the usage for MMD Access – Register/Data (Reg. Eh). RW 00 00 = Register 01 = Data, no post increment 10 = Data, post increment on reads and writes 11 = Data, post increment on writes only D.13:5 Reserved Reserved RW 00_0000_000 D.4:0 MMD – Device Address These five bits set the MMD device address. RW 0_0000 RW 0000_0000_0000_0000 Register Eh – MMD Access – Register/Data E.15:0 MMD – Register/Data For the selected MMD device address (Reg. Dh, bits [4:0]), When Reg. Dh, bits [15:14] = 00, this register contains the read/write register address for the MMD device address. Otherwise, this register contains the read/write data value for the MMD device address and its selected register address. See also Reg. Dh, bits [15:14], for descriptions of post increment reads and writes of this register for data operation. Note: 9. RW = Read/Write. RO = Read only. SC = Self-cleared. LH = Latch high. LL = Latch low. August 31, 2015 53 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Vendor-Specific Registers – Descriptions Address Name Description Mode (10) Default Register 10h – Digital Reserved Control 10.15:5 Reserved Reserved RW 0000_0000_000 10.4 PLL Off 1 = Turn PLL off automatically in EDPD mode RW 0 Reserved RW 0000 0 = Keep PLL on in EDPD mode. See also Register 18h, bit [11] for EDPD mode 10.3:0 Reserved Register 11h – AFE Control 1 11.15:6 Reserved Reserved RW 0000_0000_00 11.5 Slow-Oscillator Mode Enable Slow-oscillator mode is used to disconnect the input reference crystal/clock on the XI pin and select the on-chip slow oscillator when the KSZ8091MNX/RNB device is not in use after power-up. RW 0 Reserved RW 0_0000 1 = Enable 0 = Disable This bit automatically sets software power-down to the analog side when enabled. 11.4:0 Reserved Register 13h – AFE Control 4 13.15:5 Reserved Reserved RW 0000_0000_000 13.4 10Base-Te Mode 1 = EEE 10Base-Te (1.75V TX amplitude) RW 0 Reserved Reserved RW 0000 Receive error counter for symbol error frames RO/SC 0000h RW Set by the PME_EN strapping pin. 13.3:0 0 = Standard 10Base-T (2.5V TX amplitude) Register 15h – RXER Counter 15.15:0 RXER Counter Register 16h – Operation Mode Strap Override 16.15 PME Enable PME for Wake-on-LAN 1 = Enable See the “Strapping Options – KSZ8091MNX” section for details. 0 = Disable This bit works in conjunction with MMD Address 1Fh, Reg. 0h, Bits [15:14] to define the output for pins 21 and 30. 16.14:11 Reserved Reserved RW 000_0 16.10 Reserved Reserved RO 0 B-CAST_OFF Override 1 = Override strap-in for B-CAST_OFF RW 0 16.8 Reserved Reserved RW 0 16.7 MII B-to-B Override 1 = Override strap-in for MII back-to-back mode (also set bit 0 of this register to ‘1’) RW 0 16.9 If bit is ‘1’, PHY Address 0 is non-broadcast. This bit applies only to KSZ8091MNX. August 31, 2015 54 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (10) Address Name Description Mode Default 16.6 RMII B-to-B Override 1 = Override strap-in for RMII Back-to-Back mode (also set bit 1 of this register to ‘1’) RW 0 This bit applies only to KSZ8091RNB. 16.5 NAND Tree Override 1 = Override strap-in for NAND tree mode RW 0 16.4:2 Reserved Reserved RW 0_00 16.1 RMII Override 1 = Override strap-in for RMII mode RW 0 RW 1 This bit applies only to KSZ8091RNB. 16.0 MII Override 1 = Override strap-in for MII mode This bit applies only to KSZ8091MNX. Register 17h – Operation Mode Strap Status 17.15:13 PHYAD[2:0] Strap-In Status [000] = Strap to PHY Address 0 RO [001] = Strap to PHY Address 1 [010] = Strap to PHY Address 2 [011] = Strap to PHY Address 3 [100] = Strap to PHY Address 4 [101] = Strap to PHY Address 5 [110] = Strap to PHY Address 6 [111] = Strap to PHY Address 7 17.12:10 Reserved Reserved RO 17.9 B-CAST_OFF Strap-In Status 1 = Strap to B-CAST_OFF RO 17.8 Reserved Reserved RO 17.7 MII B-to-B Strap-In Status 1 = Strap to MII back-to-back mode RO If bit is ‘1’, PHY Address 0 is non-broadcast. This bit applies only to KSZ8091MNX. RMII B-to-B Strap-In Status 1 = Strap to RMII Back-to-Back mode 17.5 NAND Tree Strap-In Status 1 = Strap to NAND tree mode RO 17.4:2 Reserved Reserved RO 17.1 RMII Strap-In Status 1 = Strap to RMII mode RO 17.6 17.0 MII Strap-In Status RO This bit applies only to KSZ8091RNB. This bit applies only to KSZ8091RNB. 1 = Strap to MII mode RO This bit applies only to KSZ8091MNX. Register 18h – Expanded Control 18.15:12 Reserved Reserved RW 0000 18.11 EDPD Disabled Energy-detect power-down mode RW 1 1 = Disable 0 = Enable See also Register 10h, bit [4] for PLL off. August 31, 2015 55 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (10) Address Name Description Mode Default 18.10 100Base-TX Latency 1 = MII output is random latency RW 0 0 = MII output is fixed latency For both settings, all bytes of received preamble are passed to the MII output. This bit applies only to the KSZ8091MNX. 18.9:7 Reserved Reserved RW 00_0 18.6 10Base-T Preamble Restore 1 = Restore received preamble to MII output RW 0 RW 00_0001 RW 0 RW 0 RW 0 RW 0 RW 0 RW 0 RW 0 RW 0 RO/SC 0 RO/SC 0 RO/SC 0 RO/SC 0 0 = Remove all seven bytes of preamble before sending frame (starting with SFD) to MII output This bit applies only to the KSZ8091MNX. 18.5:0 Reserved Reserved Register 1Bh – Interrupt Control/Status 1B.15 1B.14 1B.13 1B.12 1B.11 1B.10 1B.9 1B.8 1B.7 1B.6 1B.5 1B.4 Jabber Interrupt Enable 1 = Enable jabber interrupt Receive Error Interrupt Enable 1 = Enable receive error interrupt Page Received Interrupt Enable 1 = Enable page received interrupt Parallel Detect Fault Interrupt Enable 1 = Enable parallel detect fault interrupt Link Partner Acknowledge Interrupt Enable 1 = Enable link partner acknowledge interrupt Link-Down Interrupt Enable 1= Enable link-down interrupt 0 = Disable jabber interrupt 0 = Disable receive error interrupt 0 = Disable page received interrupt 0 = Disable parallel detect fault interrupt 0 = Disable link partner acknowledge interrupt 0 = Disable link-down interrupt Remote Fault Interrupt Enable 1 = Enable remote fault interrupt Link-Up Interrupt Enable 1 = Enable link-up interrupt Jabber Interrupt 1 = Jabber occurred Receive Error Interrupt 1 = Receive error occurred Page Receive Interrupt 1 = Page receive occurred Parallel Detect Fault Interrupt 1 = Parallel detect fault occurred August 31, 2015 0 = Disable remote fault interrupt 0 = Disable link-up interrupt 0 = Jabber did not occur 0 = Receive error did not occur 0 = Page receive did not occur 0 = Parallel detect fault did not occur 56 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (10) Address Name Description Mode 1B.3 Link Partner Acknowledge Interrupt 1 = Link partner acknowledge occurred RO/SC 0 RO/SC 0 RO/SC 0 RO/SC 0 RW/SC 0 RO 00 1B.2 1B.1 1B.0 Default 0 = Link partner acknowledge did not occur Link-Down Interrupt 1 = Link-down occurred Remote Fault Interrupt 1 = Remote fault occurred Link-Up Interrupt 1 = Link-up occurred 0 = Link-down did not occur 0 = Remote fault did not occur 0 = Link-up did not occur Register 1Dh – LinkMD Cable Diagnostic 1D.15 1D.14:13 Cable Diagnostic Test Enable Cable Diagnostic Test Result 1 = Enable cable diagnostic test. After test has completed, this bit is self-cleared. 0 = Indicates cable diagnostic test (if enabled) has completed and the status information is valid for read. [00] = Normal condition [01] = Open condition has been detected in cable [10] = Short condition has been detected in cable [11] = Cable diagnostic test has failed 1D.12 Short Cable Indicator 1 = Short cable (<10 meter) has been detected by LinkMD RO 0 1D.11:9 Reserved Reserved RW 000 1D.8:0 Cable Fault Counter Distance to fault RO 0_0000_0000 Register 1Eh – PHY Control 1 1E.15:10 Reserved Reserved RO 0000_00 1E.9 Enable Pause (Flow Control) 1 = Flow control capable RO 0 Link Status 1 = Link is up RO 0 1E.8 0 = No flow control capability 0 = Link is down 1E.7 Polarity Status 1 = Polarity is reversed RO 0 = Polarity is not reversed 1E.6 Reserved Reserved RO 1E.5 MDI/MDI-X State 1 = MDI-X RO Energy Detect 1 = Signal present on receive differential pair 1E.4 0 0 = MDI RO 0 RW 0 0 = No signal detected on receive differential pair 1E.3 PHY Isolate 1 = PHY in isolate mode 0 = PHY in normal operation August 31, 2015 57 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (10) Address Name Description Mode Default 1E.2:0 Operation Mode Indication [000] = Still in auto-negotiation RO 000 RW 1 RW 0 RW 0 [001] = 10Base-T half-duplex [010] = 100Base-TX half-duplex [011] = Reserved [100] = Reserved [101] = 10Base-T full-duplex [110] = 100Base-TX full-duplex [111] = Reserved Register 1Fh – PHY Control 2 1F.15 HP_MDIX 1 = HP Auto MDI/MDI-X mode 0 = Micrel Auto MDI/MDI-X mode 1F.14 MDI/MDI-X Select When Auto MDI/MDI-X is disabled, 1 = MDI-X mode Transmit on RXP,RXM (pins 5, 4) and Receive on TXP,TXM (pins 7, 6) 0 = MDI mode Transmit on TXP,TXM (pins 7, 6) and Receive on RXP,RXM (pins 5, 4) 1F.13 Pair Swap Disable 1 = Disable Auto MDI/MDI-X 1F.12 Reserved Reserved RW 0 1F.11 Force Link 1 = Force link pass RW 0 RW 0 RW 0 RW 1 RW 0 RW 0 0 = Enable Auto MDI/MDI-X 0 = Normal link operation This bit bypasses the control logic and allows the transmitter to send a pattern even if there is no link. 1F.10 Power Saving 1 = Enable power saving 0 = Disable power saving 1F.9 Interrupt Level 1 = Interrupt pin active high 0 = Interrupt pin active low 1F.8 Enable Jabber 1 = Enable jabber counter 0 = Disable jabber counter 1F.7 RMII Reference Clock Select 1 = RMII 50MHz clock mode; clock input to XI (pin 9) is 50MHz 0 = RMII 25MHz clock mode; clock input to XI (pin 9) is 25MHz This bit applies only to KSZ8091RNB. 1F.6 Reserved August 31, 2015 Reserved 58 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (10) Address Name Description Mode Default 1F.5:4 LED Mode [00] = LED1: Speed RW 00 RW 0 RW 0 RW 0 RW 0 LED0: Link/Activity [01] = LED1: Activity LED0: Link [10], [11] = Reserved The LED1 pin applies only to the KSZ8091RNB. 1F.3 1F.2 1F.1 1F.0 Disable Transmitter 1 = Disable transmitter Remote Loopback 1 = Remote (analog) loopback is enabled 0 = Enable transmitter 0 = Normal mode Enable SQE Test 1 = Enable SQE test Disable Data Scrambling 1 = Disable scrambler 0 = Disable SQE test 0 = Enable scrambler Note: 10. RW = Read/Write. RO = Read only. SC = Self-cleared. August 31, 2015 59 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MMD Registers MMD registers provide indirect read/write access to up to 32 MMD Device Addresses with each device supporting up to 65,536 16-bit registers, as defined in Clause 22 of the IEEE 802.3 Specification. The KSZ8091MNX/RNB, however, uses only a small fraction of the available registers. See the “Register Map” section for a list of supported MMD device addresses and their associated register addresses. The following two standard registers serve as the portal registers to access the indirect MMD registers. • Standard register Dh – MMD Access – Control • Standard register Eh – MMD Access – Register/Data Table 15. Portal Registers (Access to Indirect MMD Registers) Address Name Description Mode Default RW 00 Register Dh – MMD Access – Control D.15:14 MMD – Operation Mode For the selected MMD device address (bits [4:0] of this register), these two bits select one of the following register or data operations and the usage for MMD Access – Register/Data (Reg. Eh). 00 = Register 01 = Data, no post increment 10 = Data, post increment on reads and writes 11 = Data, post increment on writes only D.13:5 Reserved Reserved RW 00_0000_000 D.4:0 MMD – Device Address These five bits set the MMD device address. RW 0_0000 RW 0000_0000_0000_0000 Register Eh – MMD Access – Register/Data E.15:0 MMD – Register/Data For the selected MMD device address (Reg. Dh, bits [4:0]), When Reg. Dh, bits [15:14] = 00, this register contains the read/write register address for the MMD device address. Otherwise, this register contains the read/write data value for the MMD device address and its selected register address. See also Register Dh, bits [15:14] descriptions for post increment reads and writes of this register for data operation. Examples: MMD Register Write Write MMD – Device Address 1Fh, Register 0h = 0001h to enable link-up detection to trigger PME for WOL. 1. Write Register Dh with 001Fh // Set up register address for MMD – Device Address 1Fh. 2. Write Register Eh with 0000h // Select register 0h of MMD – Device Address 1Fh. 3. Write Register Dh with 401Fh // Select register data for MMD – Device Address 1Fh, Register 0h. 4. Write Register Eh with 0001h // Write value 0001h to MMD – Device Address 1Fh, Register 0h. August 31, 2015 60 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MMD Register Read Read MMD – Device Address 1Fh, Register 19h – 1Bh for the magic packet’s MAC address 1. Write Register Dh with 001Fh // Set up register address for MMD – Device Address 1Fh. 2. Write Register Eh with 0019h // Select Register 19h of MMD – Device Address 1Fh. 3. Write Register Dh with 801Fh // Select register data for MMD – Device Address 1Fh, Register 19h // with post increments 4. Read Register Eh // Read data in MMD – Device Address 1Fh, Register 19h. 5. Read Register Eh // Read data in MMD – Device Address 1Fh, Register 1Ah. 6. Read Register Eh // Read data in MMD – Device Address 1Fh, Register 1Bh. MMD Registers – Descriptions Address Name Description Mode (11) Default MMD Address 1h, Register 0h – PMA/PMD Control 1 1.0.15:13 Reserved Reserved RW 000 1.0.12 LPI enable Lower Power Idle enable RW 0 1.0.11:0 Reserved Reserved RW 0000_0000_0000 MMD Address 1h, Register 1h – PMA/PMD Status 1 1.1.15:9 Reserved Reserved RO 0000_000 1.1.8 LPI State Entered 1 = PMA/PMD has entered LPI state RO/LH 0 1.1.7:4 Reserved Reserved RO 0000 1.1.3 LPI State Indication 1 = PMA/PMD is currently in LPI state RO 0 RO 000 1.1.2:0 Reserved 0 = PMA/PMD has not entered LPI state 0 = PMA/PMD is currently not in LPI state Reserved MMD Address 3h, Register 0h – EEE PCS Control 1 3.0.15:12 Reserved Reserved RO 0000 3.0.11 Reserved Reserved RW 1 3.0.10 100Base-TX RXC Clock Stoppable During receive lower-power idle mode, RW 1 1 = RXC clock is stoppable for 100Base-TX 0 = RXC clock is not stoppable for 100Base-TX This bit applies only to KSZ8091MNX. 3.0.9:4 Reserved Reserved RW 00_0001 3.0.3:2 Reserved Reserved RO 00 3.0.1:0 Reserved Reserved RW 00 MMD Address 7h, Register 3Ch – EEE Advertisement 7.3C.15:3 Reserved Reserved RO 0000_0000_0000_0 7.3C.2 1000Base-T EEE Capable 0 = 1000Mbps EEE is not supported RO 0 August 31, 2015 61 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB (11) Address Name Description Mode Default 7.3C.1 100Base-TX EEE Capable 1 = 100Mbps EEE capable RW 0 RO 0 0 = No 100Mbps EEE capability This bit is set to ‘0’ as the default after power-up or reset. Set this bit to ‘1’ to enable 100Mbps EEE mode. 7.3C.0 Reserved Reserved MMD Address 7h, Register 3Dh – EEE Link Partner Advertisement 7.3D.15:3 Reserved Reserved RO 0000_0000_0000_0 7.3D.2 1000Base-T EEE Capable 1 = 1000Mbps EEE capable RO 0 7.3D.1 100Base-TX EEE Capable 1 = 100Mbps EEE capable RO 0 7.3D.0 Reserved Reserved RO 0 RW 00 0 = No 1000Mbps EEE capability 0 = No 100Mbps EEE capability MMD Address 1Fh, Register 0h – Wake-On-LAN – Control 1F.0.15:14 PME Output Select These two bits work in conjunction with Reg. 16h, Bit [15] for PME enable to define the output for pins 21 and 30. INTRP/PME_N2 (pin 21) 00 = INTRP output 01 = PME_N2 output 10 = INTRP and PME_N2 output 11 = Reserved LED0/PME_N1 (pin 30) 00 = PME_N1 output 01 = LED0 output 10 = LED0 output 11 = PME_N1 output 1F.0.13:7 Reserved Reserved RO 00_0000_0 1F.0.6 Magic Packet Detect Enable 1 = Enable magic-packet detection RW 0 RW 0 RW 0 RW 0 RW 0 RW 0 1F.0.5 1F.0.4 1F.0.3 1F.0.2 1F.0.1 CustomPacket Type 3 Detect Enable CustomPacket Type 2 Detect Enable CustomPacket Type 1 Detect Enable CustomPacket Type 0 Detect Enable Link-Down Detect Enable August 31, 2015 0 = Disable magic-packet detection 1 = Enable custom-packet, Type 3 detection 0 = Disable custom-packet, Type 3 detection 1 = Enable custom-packet, Type 2 detection 0 = Disable custom-packet, Type 2 detection 1 = Enable custom-packet, Type 1 detection 0 = Disable custom-packet, Type 1 detection 1 = Enable custom-packet, Type 0 detection 0 = Disable custom-packet, Type 0 detection 1 = Enable link-down detection 0 = Disable link-down detection 62 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Address Name Description Mode 1F.0.0 Link-Up Detect Enable 1 = Enable link-up detection RW (11) Default 0 0 = Disable link-up detection MMD Address 1Fh, Register 1h – Wake-On-LAN – Customized Packet, Type 0, Mask 0 MMD Address 1Fh, Register 7h – Wake-On-LAN – Customized Packet, Type 1, Mask 0 MMD Address 1Fh, Register Dh – Wake-On-LAN – Customized Packet, Type 2, Mask 0 MMD Address 1Fh, Register 13h – Wake-On-LAN – Customized Packet, Type 3, Mask 0 1F.1.15:0 1F.7.15:0 Custom Packet Type X Mask 0 1F.D.15:0 This register selects the bytes in the first 16 bytes of the packet (bytes 1 thru 16) that will be used for CRC calculation. RW 0000_0000_0000_0000 For each bit in this register, 1F.13.15:0 1 = Byte is selected for CRC calculation 0 = Byte is not selected for CRC calculation The register-bit to packet-byte mapping is as follows: Bit [15] : byte-16 … : … Bit [1] : byte-2 Bit [0] : byte-1 MMD Address 1Fh, Register 2h – Wake-On-LAN – Customized Packet, Type 0, Mask 1 MMD Address 1Fh, Register 8h – Wake-On-LAN – Customized Packet, Type 1, Mask 1 MMD Address 1Fh, Register Eh – Wake-On-LAN – Customized Packet, Type 2, Mask 1 MMD Address 1Fh, Register 14h – Wake-On-LAN – Customized Packet, Type 3, Mask 1 1F.2.15:0 1F.8.15:0 Custom Packet Type X Mask 1 1F.E.15:0 1F.14.15:0 This register selects the bytes in the second 16 bytes of the packet (bytes 17 thru 32) that will be used for CRC calculation. RW 0000_0000_0000_0000 For each bit in this register, 1 = Byte is selected for CRC calculation 0 = Byte is not selected for CRC calculation The register-bit to packet-byte mapping is as follows: August 31, 2015 Bit [15] : byte-32 … : … Bit [1] : byte-18 Bit [0] : byte-17 63 Revision 1.2 Micrel, Inc. Address KSZ8091MNX/KSZ8091RNB Name Description Mode (11) Default MMD Address 1Fh, Register 3h – Wake-On-LAN – Customized Packet, Type 0, Mask 2 MMD Address 1Fh, Register 9h – Wake-On-LAN – Customized Packet, Type 1, Mask 2 MMD Address 1Fh, Register Fh – Wake-On-LAN – Customized Packet, Type 2, Mask 2 MMD Address 1Fh, Register 15h – Wake-On-LAN – Customized Packet, Type 3, Mask 2 1F.3.15:0 1F.9.15:0 Custom Packet Type X Mask 2 1F.F.15:0 This register selects the bytes in the third 16 bytes of the packet (bytes 33 thru 48) that will be used for CRC calculation. RW 0000_0000_0000_0000 For each bit in this register, 1F.15.15:0 1 = Byte is selected for CRC calculation 0 = Byte is not selected for CRC calculation The register-bit to packet-byte mapping is as follows: Bit [15] : byte-48 … : … Bit [1] : byte-34 Bit [0] : byte-33 MMD Address 1Fh, Register 4h – Wake-On-LAN – Customized Packet, Type 0, Mask 3 MMD Address 1Fh, Register Ah – Wake-On-LAN – Customized Packet, Type 1, Mask 3 MMD Address 1Fh, Register 10h – Wake-On-LAN – Customized Packet, Type 2, Mask 3 MMD Address 1Fh, Register 16h – Wake-On-LAN – Customized Packet, Type 3, Mask 3 1F.4.15:0 1F.A.15:0 Custom Packet Type X Mask 3 1F.10.15:0 This register selects the bytes in the fourth 16 bytes of the packet (bytes 49 thru 64) that will be used for CRC calculation. RW 0000_0000_0000_0000 For each bit in this register, 1F.16.15:0 1 = Byte is selected for CRC calculation 0 = Byte is not selected for CRC calculation The register-bit to packet-byte mapping is as follows: Bit [15] : byte-64 … : … Bit [1] : byte-50 Bit [0] : byte-49 MMD Address 1Fh, Register 5h – Wake-On-LAN – Customized Packet, Type 0, Expected CRC 0 MMD Address 1Fh, Register Bh – Wake-On-LAN – Customized Packet, Type 1, Expected CRC 0 MMD Address 1Fh, Register 11h – Wake-On-LAN – Customized Packet, Type 2, Expected CRC 0 MMD Address 1Fh, Register 17h – Wake-On-LAN – Customized Packet, Type 3, Expected CRC 0 1F.5.15:0 1F.B.15:0 Custom Packet Type X CRC 0 1F.11.15:0 1F.17.15:0 This register stores the lower two bytes for the expected CRC. RW 0000_0000_0000_0000 Bit [15:8] = Byte 2 (CRC [15:8]) Bit [7:0] = Byte 1 (CRC [7:0]) The upper two bytes for the expected CRC are stored in the following register. August 31, 2015 64 Revision 1.2 Micrel, Inc. Address KSZ8091MNX/KSZ8091RNB Name Description Mode (11) Default MMD Address 1Fh, Register 6h – Wake-On-LAN – Customized Packet, Type 0, Expected CRC 1 MMD Address 1Fh, Register Ch – Wake-On-LAN – Customized Packet, Type 1, Expected CRC 1 MMD Address 1Fh, Register 12h – Wake-On-LAN – Customized Packet, Type 2, Expected CRC 1 MMD Address 1Fh, Register 18h – Wake-On-LAN – Customized Packet, Type 3, Expected CRC 1 1F.6.15:0 1F.C.15:0 Custom Packet Type X CRC 1 1F.12.15:0 This register stores the upper two bytes for the expected CRC. RW 0000_0000_0000_0000 RW 0000_0000_0000_0000 RW 0000_0000_0000_0000 RW 0000_0000_0000_0000 Bit [15:8] = Byte 4 (CRC [31:24]) Bit [7:0] = Byte 3 (CRC [23:16]) 1F.18.15:0 The lower two bytes for the expected CRC are stored in the previous register. MMD Address 1Fh, Register 19h – Wake-On-LAN – Magic Packet, MAC-DA-0 1F.19.15:0 Magic Packet MAC-DA-0 This register stores the lower two bytes of the destination MAC address for the magic packet. Bit [15:8] = Byte 2 (MAC Address [15:8]) Bit [7:0] = Byte 1 (MAC Address [7:0]) The upper four bytes of the destination MAC address are stored in the following two registers. MMD Address 1Fh, Register 1Ah – Wake-On-LAN – Magic Packet, MAC-DA-1 1F.1A.15:0 Magic Packet MAC-DA-1 This register stores the middle two bytes of the destination MAC address for the magic packet. Bit [15:8] = Byte 4 (MAC Address [31:24]) Bit [7:0] = Byte 3 (MAC Address [23:16]) The lower two bytes and upper two bytes of the destination MAC address are stored in the previous and following registers, respectively. MMD Address 1Fh, Register 1Bh – Wake-On-LAN – Magic Packet, MAC-DA-2 1F.1B.15:0 Magic Packet MAC-DA-2 This register stores the upper two bytes of the destination MAC address for the magic packet. Bit [15:8] = Byte 6 (MAC Address [47:40]) Bit [7:0] = Byte 5 (MAC Address [39:32]) The lower four bytes of the destination MAC address are stored in the previous two registers. Note: 11. RW = Read/Write. RO = Read only. LH = Latch high. August 31, 2015 65 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Absolute Maximum Ratings(12) Operating Ratings(13) Supply Voltage (VIN) (VDD_1.2) .................................................. −0.5V to +1.8V (VDDIO, VDDA_3.3) ....................................... −0.5V to +5.0V Input Voltage (all inputs) .............................. −0.5V to +5.0V Output Voltage (all outputs) ......................... −0.5V to +5.0V Lead Temperature (soldering, 10s) ............................ 260°C Storage Temperature (Ts) ......................... –55°C to +150°C Supply Voltage (VDDIO_3.3, VDDA_3.3) .......................... +3.135V to +3.465V (VDDIO_2.5)........................................ +2.375V to +2.625V (VDDIO_1.8)........................................ +1.710V to +1.890V Ambient Temperature (TA, Commercial) ...................................... 0°C to +70°C (TA, Industrial) ....................................... –40°C to +85°C Maximum Junction Temperature (TJ max.) ................ 125°C Thermal Resistance (θJA) ......................................... 34°C/W Thermal Resistance (θJC) ........................................... 6°C/W Electrical Characteristics(14) Symbol Parameter Condition Min. Typ. Max. Units (15) Supply Current (VDDIO, VDDA_3.3 = 3.3V) IDD1_3.3V 10Base-T Full-duplex traffic @ 100% utilization 41 mA IDD2_3.3V 100Base-TX Full-duplex traffic @ 100% utilization 47 mA IDD3_3.3V EEE (100Mbps) Mode TX and RX paths in LPI state with no traffic 23 mA IDD4_3.3V EDPD Mode Ethernet cable disconnected (Reg. 18h.11 = 0) 20 mA IDD5_3.3V Power-Down Mode Software power-down (Reg. 0h.11 = 1) 4 mA CMOS Level Inputs VIH VIL |IIN| Input High Voltage Input Low Voltage Input Current VDDIO = 3.3V 2.0 V VDDIO = 2.5V 1.8 V VDDIO = 1.8V 1.3 V VDDIO = 3.3V 0.8 V VDDIO = 2.5V 0.7 V VDDIO = 1.8V 0.5 V VIN = GND ~ VDDIO 10 µA CMOS Level Outputs VOH VOL |Ioz| Output High Voltage Output Low Voltage VDDIO = 3.3V 2.4 V VDDIO = 2.5V 2.0 V VDDIO = 1.8V 1.5 V VDDIO = 3.3V 0.4 V VDDIO = 2.5V 0.4 V VDDIO = 1.8V 0.3 V 10 µA Output Tri-State Leakage LED Output ILED Output Drive Current Each LED pin (LED0, LED1) 8 mA Notes: 12. Exceeding the absolute maximum ratings may damage the device. Stresses greater than the absolute maximum rating can cause permanent damage to the device. Operation of the device at these or any other conditions above those specified in the operating sections of this specification is not implied. Maximum conditions for extended periods may affect reliability. 13. The device is not guaranteed to function outside its operating ratings. 14. TA = 25°C. Specification for packaged product only. 15. Current consumption is for the single 3.3V supply KSZ8091MNX/RNB device only, and includes the transmit driver current and the 1.2V supply voltage (VDD_1.2) that are supplied by the KSZ8091MNX/RNB. August 31, 2015 66 Revision 1.2 Micrel, Inc. Symbol KSZ8091MNX/KSZ8091RNB Parameter Condition Min. Typ. Max. Units VDDIO = 3.3V 30 45 73 kΩ VDDIO = 2.5V 39 61 102 kΩ VDDIO = 1.8V 48 99 178 kΩ VDDIO = 3.3V 26 43 79 kΩ VDDIO = 2.5V 34 59 113 kΩ VDDIO = 1.8V 53 99 200 kΩ 1.05 V 2 % 5 ns All Pull-Up/Pull-Down Pins (including Strapping Pins) pu pd Internal Pull-Up Resistance Internal Pull-Down Resistance 100Base-TX Transmit (measured differentially after 1:1 transformer) VO Peak Differential Output Voltage 100Ω termination across differential output 0.95 VIMB Output Voltage Imbalance 100Ω termination across differential output tr , tf Rise/Fall Time 3 Rise/Fall Time Imbalance 0 Duty Cycle Distortion Overshoot Output Jitter Peak-to-peak 0.5 ns ±0.25 ns 5 % 0.7 ns 10Base-T Transmit (measured differentially after 1:1 transformer) VP tr , tf Peak Differential Output Voltage 100Ω termination across differential output Jitter Added Peak-to-peak 2.2 Rise/Fall Time 2.8 V 3.5 ns 25 ns 5MHz square wave 400 mV R(ISET) = 6.49kΩ 0.65 V Peak-to-peak 300 ps 10Base-T Receive VSQ Squelch Threshold Transmitter – Drive Setting VSET Reference Voltage of ISET REF_CLK Output 50MHz RMII Clock Output Jitter (Applies only to KSZ8091RNB in RMII – 25MHz clock mode) 100Mbps Mode – Industrial Applications Parameters Clock Phase Delay – XI Input to MII TXC Output XI (25MHz clock input) to MII TXC (25MHz clock output) delay, referenced to rising edges of both clocks. 15 20 25 ns (Applies only to KSZ8091MNX in MII mode) tllr Link Loss Reaction (Indication) Time Link loss detected at receive differential inputs to PHY signal indication time for each of the following: 4.4 µs 1. For LED mode 00 (KSZ8091RNB only), Speed LED output changes from low (100Mbps) to high (10Mbps, default state for link-down). 2. For LED mode 01, Link LED output changes from low (link-up) to high (link-down). 3. INTRP pin asserts for link-down status change. August 31, 2015 67 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Timing Diagrams MII SQE Timing (10Base-T) Figure 16. MII SQE Timing (10Base-T) Table 16. MII SQE Timing (10Base-T) Parameters Timing Parameter Description tP TXC period 400 ns tWL TXC pulse width low 200 ns tWH TXC pulse width high 200 ns tSQE COL (SQE) delay after TXEN de-asserted 2.2 µs tSQEP COL (SQE) pulse duration 1.0 µs August 31, 2015 Min. 68 Typ. Max. Unit Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MII Transmit Timing (10Base-T) Figure 17. MII Transmit Timing (10Base-T) Table 17. MII Transmit Timing (10Base-T) Parameters Timing Parameter Description tP TXC period 400 ns tWL TXC pulse width low 200 ns tWH TXC pulse width high 200 ns tSU1 TXD[3:0] setup to rising edge of TXC 120 ns tSU2 TXEN setup to rising edge of TXC 120 ns tHD1 TXD[3:0] hold from rising edge of TXC 0 ns tHD2 TXEN hold from rising edge of TXC 0 ns tCRS1 TXEN high to CRS asserted latency 600 ns tCRS2 TXEN low to CRS de-asserted latency 1.0 µs August 31, 2015 Min. 69 Typ. Max. Unit Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MII Receive Timing (10Base-T) Figure 18. MII Receive Timing (10Base-T) Table 18. MII Receive Timing (10Base-T) Parameters Timing Parameter Description tP RXC period 400 ns tWL RXC pulse width low 200 ns tWH RXC pulse width high 200 ns tOD (RXDV, RXD[3:0], RXER) output delay from rising edge of RXC 205 ns tRLAT CRS to (RXDV, RXD[3:0]) latency 7.2 µs August 31, 2015 Min. 70 Typ. Max. Unit Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MII Transmit Timing (100Base-TX) Figure 19. MII Transmit Timing (100Base-TX) Table 19. MII Transmit Timing (100Base-TX) Parameters Timing Parameter Description tP TXC period 40 ns tWL TXC pulse width low 20 ns tWH TXC pulse width high 20 ns tSU1 TXD[3:0] setup to rising edge of TXC 10 ns tSU2 TXEN setup to rising edge of TXC 10 ns tHD1 TXD[3:0] hold from rising edge of TXC 0 ns tHD2 TXEN hold from rising edge of TXC 0 ns tCRS1 TXEN high to CRS asserted latency 72 ns tCRS2 TXEN low to CRS de-asserted latency 72 ns August 31, 2015 Min. 71 Typ. Max. Unit Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MII Receive Timing (100Base-TX) Figure 20. MII Receive Timing (100Base-TX) Table 20. MII Receive Timing (100Base-TX) Parameters Timing Parameter Description tP RXC period 40 ns tWL RXC pulse width low 20 ns tWH RXC pulse width high 20 ns tOD (RXDV, RXD[3:0], RXER) output delay from rising edge of RXC tRLAT CRS to (RXDV, RXD[3:0]) latency August 31, 2015 Min. 16 Typ. 21 170 72 Max. 25 Unit ns ns Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB RMII Timing Figure 21. RMII Timing – Data Received from RMII Figure 22. RMII Timing – Data Input to RMII Table 21. RMII Timing Parameters – KSZ8091RNB (25MHz input to XI pin, 50MHz output from REF_CLK pin) Timing Parameter Description tCYC Clock cycle t1 Setup time Min. Typ. Max. 20 Unit ns 4 ns t2 Hold time 2 tOD Output delay 7 10 13 ns ns Min. Typ. Max. Unit Table 22. RMII Timing Parameters – KSZ8091RNB (50MHz input to XI pin) Timing Parameter Description tCYC Clock cycle t1 Setup time 4 ns t2 Hold time 2 ns tOD Output delay 8 August 31, 2015 20 73 11 ns 13 ns Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Auto-Negotiation Timing Figure 23. Auto-Negotiation Fast Link Pulse (FLP) Timing Table 23. Auto-Negotiation Fast Link Pulse (FLP) Timing Parameters Timing Parameter Description tBTB FLP burst to FLP burst tFLPW FLP burst width tPW Clock/Data pulse width tCTD Clock pulse to data pulse 55.5 64 69.5 µs tCTC Clock pulse to clock pulse 111 128 139 µs Number of clock/data pulses per FLP burst 17 August 31, 2015 74 Min. Typ. Max. Unit 8 16 24 ms 2 ms 100 ns 33 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MDC/MDIO Timing Figure 24. MDC/MDIO Timing Table 24. MDC/MDIO Timing Parameters Timing Parameter Description fc tP tMD1 MDIO (PHY input) setup to rising edge of MDC 10 ns tMD2 MDIO (PHY input) hold from rising edge of MDC 4 ns tMD3 MDIO (PHY output) delay from rising edge of MDC 5 August 31, 2015 Min. Typ. Max. Unit MDC Clock Frequency 2.5 10 MHz MDC period 400 75 222 ns ns Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Power-Up/Reset Timing The KSZ8091MNX/RNB reset timing requirement is summarized in Figure 25 and Table 25. Figure 25. Power-Up/Reset Timing Table 25. Power-Up/Reset Timing Parameters Timing Parameter Description Min. Typ. Max. Unit tVR Supply voltage (VDDIO, VDDA_3.3) rise time 300 µs tSR Stable supply voltage (VDDIO, VDDA_3.3) to reset high 10 ms tCS Configuration setup time 5 ns tCH Configuration hold time 5 ns tRC Reset to strap-in pin output 6 ns The supply voltage (VDDIO and VDDA_3.3) power-up waveform should be monotonic. The 300µs minimum rise time is from 10% to 90%. For warm reset, the reset (RST#) pin should be asserted low for a minimum of 500µs. The strap-in pin values are read and updated at the de-assertion of reset. After the de-assertion of reset, wait a minimum of 100µs before starting programming on the MIIM (MDC/MDIO) interface. August 31, 2015 76 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Reset Circuit Figure 26 shows a reset circuit recommended for powering up the KSZ8091MNX/RNB if reset is triggered by the power supply. Figure 26. Recommended Reset Circuit Figure 27 Shows a reset circuit recommended for applications where reset is driven by another device (for example, the CPU or an FPGA). The reset out RST_OUT_n from CPU/FPGA provides the warm reset after power up reset. D2 is used if using different VDDIO between the switch and CPU/FPGA, otherwise, the different VDDIO will fight each other. If different VDDIO have to use in a special case, a low VF (<0.3V) diode is required (For example, VISHAY’s BAT54, MSS1P2L and so on), or a level shifter device can be used too. If Ethernet device and CPU/FPGA use same VDDIO voltage, D2 can be removed to connect both devices directly. Usually, Ethernet device and CPU/FPGA should use same VDDIO voltage. Figure 27. Recommended Reset Circuit for Interfacing with CPU/FPGA Reset Output August 31, 2015 77 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Reference Circuits – LED Strap-In Pins The pull-up, float, and pull-down reference circuits for the LED1/SPEED and LED0/PME_N1/NWAYEN strapping pins are shown in Figure 28 for 3.3V and 2.5V VDDIO. Figure 28. Reference Circuits for LED Strapping Pins For 1.8V VDDIO, LED indication support is not recommended due to the low voltage. Without the LED indicator, the SPEED and NWAYEN strapping pins are functional with a 4.7kΩ pull-up to 1.8V VDDIO or float for a value of ‘1’, and with a 1.0kΩ pull-down to ground for a value of ‘0’. Note: If using RJ45 jacks with integrated LEDs and 1.8V VDDIO, a level shifting is required from LED 3.3V to 1.8V. For example, use a bipolar transistor or a level shift device. August 31, 2015 78 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Reference Clock – Connection and Selection A crystal or external clock source, such as an oscillator, is used to provide the reference clock for the KSZ8091MNX/RNB. For the KSZ8091MNX in all operating modes and for the KSZ8091RNB in RMII – 25MHz Clock Mode, the reference clock is 25MHz. The reference clock connections to XI (pin 9) and XO (pin 8), and the reference clock selection criteria, are provided in Figure 29 and Table 26. Figure 29. 25MHz Crystal/Oscillator Reference Clock Connection Table 26. 25MHz Crystal/Reference Clock Selection Criteria Characteristics Value Units Frequency 25 MHz Frequency tolerance (max.)() ±50 ppm Crystal series resistance (typ.) 40 Ω Crystal load capacitance (typ.) 22 pF Note: 16. ±60ppm for overtemperature crystal. For the KSZ8091RNB in RMII – 50MHz clock mode, the reference clock is 50MHz. The reference clock connections to XI (pin 9), and the reference clock selection criteria are provided in Figure 30 and Table 27. Figure 30. 50MHz Oscillator Reference Clock Connection Table 27. 50MHz Oscillator/Reference Clock Selection Criteria Characteristics Value Units Frequency 50 MHz Frequency tolerance (max.) ±50 ppm August 31, 2015 79 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Magnetic – Connection and Selection A 1:1 isolation transformer is required at the line interface. Use one with integrated common-mode chokes for designs exceeding FCC requirements. The KSZ8091MNX/RNB design incorporates voltage-mode transmit drivers and on-chip terminations. With the voltage-mode implementation, the transmit drivers supply the common-mode voltages to the two differential pairs. Therefore, the two transformer center tap pins on the KSZ8091MNX/RNB side should not be connected to any power supply source on the board; instead, the center tap pins should be separated from one another and connected through separate 0.1µF common-mode capacitors to ground. Separation is required because the common-mode voltage is different between transmitting and receiving differential pairs. Figure 31 shows the typical magnetic interface circuit for the KSZ8091MNX/RNB. Figure 31. Typical Magnetic Interface Circuit August 31, 2015 80 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Table 28 lists recommended magnetic characteristics. Table 28. Magnetics Selection Criteria Parameter Value Test Condition Turns ratio 1 CT : 1 CT Open-circuit inductance (min.) 350µH 100mV, 100kHz, 8mA Insertion loss (typ.) –1.1dB 100kHz to 100MHz HIPOT (min.) 1500Vrms Table 29 is a list of compatible single-port magnetics with separated transformer center tap pins on the PHY chip side that can be used with the KSZ8091MNX/RNB. Table 29. Compatible Single-Port 10/100 Magnetics Manufacturer Part Number Temperature Range Magnetic + RJ-45 Bel Fuse S558-5999-U7 0°C to 70°C No Bel Fuse SI-46001-F 0°C to 70°C Yes Bel Fuse SI-50170-F 0°C to 70°C Yes Delta LF8505 0°C to 70°C No HALO HFJ11-2450E 0°C to 70°C Yes HALO TG110-E055N5 –40°C to 85°C No LANKom LF-H41S-1 0°C to 70°C No Pulse H1102 0°C to 70°C No Pulse H1260 0°C to 70°C No Pulse HX1188 –40°C to 85°C No Pulse J00-0014 0°C to 70°C Yes Pulse JX0011D21NL –40°C to 85°C Yes TDK TLA-6T718A 0°C to 70°C Yes Transpower HB726 0°C to 70°C No Wurth/Midcom 000-7090-37R-LF1 –40°C to 85°C No August 31, 2015 81 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB Package Information and Recommended Land Pattern(17) 32-Pin (5mm x 5mm) QFN Note: 17. Package information is correct as of the publication date. For updates and most current information, go to www.micrel.com. August 31, 2015 82 Revision 1.2 Micrel, Inc. KSZ8091MNX/KSZ8091RNB MICREL, INC. 2180 FORTUNE DRIVE SAN JOSE, CA 95131 USA TEL +1 (408) 944-0800 FAX +1 (408) 474-1000 WEB http://www.micrel.com Micrel, Inc. is a leading global manufacturer of IC solutions for the worldwide high performance linear and power, LAN, and timing & communications markets. The Company’s products include advanced mixed-signal, analog & power semiconductors; high-performance communication, clock management, MEMs-based clock oscillators & crystal-less clock generators, Ethernet switches, and physical layer transceiver ICs. Company customers include leading manufacturers of enterprise, consumer, industrial, mobile, telecommunications, automotive, and computer products. Corporation headquarters and state-of-the-art wafer fabrication facilities are located in San Jose, CA, with regional sales and support offices and advanced technology design centers situated throughout the Americas, Europe, and Asia. Additionally, the Company maintains an extensive network of distributors and reps worldwide. Micrel makes no representations or warranties with respect to the accuracy or completeness of the information furnished in this datasheet. This information is not intended as a warranty and Micrel does not assume responsibility for its use. Micrel reserves the right to change circuitry, specifications and descriptions at any time without notice. No license, whether express, implied, arising by estoppel or otherwise, to any intellectual property rights is granted by this document. Except as provided in Micrel’s terms and conditions of sale for such products, Micrel assumes no liability whatsoever, and Micrel disclaims any express or implied warranty relating to the sale and/or use of Micrel products including liability or warranties relating to fitness for a particular purpose, merchantability, or infringement of any patent, copyright, or other intellectual property right. Micrel Products are not designed or authorized for use as components in life support appliances, devices or systems where malfunction of a product can reasonably be expected to result in personal injury. Life support devices or systems are devices or systems that (a) are intended for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant injury to the user. A Purchaser’s use or sale of Micrel Products for use in life support appliances, devices or systems is a Purchaser’s own risk and Purchaser agrees to fully indemnify Micrel for any damages resulting from such use or sale. © 2013 Micrel, Incorporated. August 31, 2015 83 Revision 1.2