DATASHEET 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 9EX21501A Description Features/Benefits: The ICS9EX21501 provides 15 output clocks for PCIe Gen2 (100MHz) or QPI (133MHz) applications. A differential CPU clock from a CK410B+ main clock generator, such as the ICS932S421, drives the ICS9EX21501. In fanout mode, the ICS9EX21501 provides outputs up to 400MHz. A 2:1 input mux allows selection between local and remote clock sources. • Recommended Application: • • • 15 Output PCIe G2/QPI Differential Buffer with 2:1 input mux • Key Specifications: • • • • DIF output cycle-to-cycle jitter < 50ps DIF output-to-output skew < 150 ps PCIe Gen2 compliant phase jitter QPI 6.4Gb/s 12UI compliant phase jitter Output clock frequencies up to 400 MHz/supports wide range of applications 4 Selectable SMBus addresses/multiple devices can share SMBus segment SMBus address independent of PLL operating mode/ maximum flexibility Dedicated CKPWRGD/PD# and VDDA pins/Easy board design 8 Dedicated OE# and 2 Group OE# pins/Support for hardware clock management Output Features: • • • • • 15 - 0.7V current-mode differential HCSL output pairs Supports zero delay buffer mode and fanout mode Selectable PLL bandwidth 80-150 MHz in PLL Mode 33-400 MHz operation in Bypass mode Functional Block Diagram OE13_14# OE(5:12)#, OE_01234# 10 CLKA_IN CLKA_IN# PLL (SS Compatible) 15 DIF(14:0) CLKB_IN CLKB_IN# HIBW_BYPM_LOBW# 100M_133M# CKPWRGD/PD# SMB_A0 SMB_A1 SEL_A_B# SMBDAT SMBCLK Logic IREF IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—07/18/11 1 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux VDD OE7# DIF_7 DIF_7# 100M_133M# SMBCLK SMBDAT SMB_A1 SMB_A0 SEL_A_B# CKPWRGD/PD# DIF_8 DIF_8# OE8# VDD PIn Configuration HIBW_BYPM_LOBW# Datasheet 64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 OE9# DIF_9 DIF_9# OE10# DIF_10 DIF_10# OE11# DIF_11 DIF_11# GND VDD DIF_12 DIF_12# OE12# DIF_13 DIF_13# 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 9EX21501 DIF_6# DIF_6 OE6# DIF_5# DIF_5 OE5# DIF_4# DIF_4 DIF_3# DIF_3 GND VDD DIF_2# DIF_2 DIF_1# DIF_1 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 DIF_0# DIF_0 OE_01234# VDD CLKB_IN# CLKB_IN GND CLKA_IN# CLKA_IN VDDA GNDA IREF DIF_14# DIF_14 OE13_14# VDD 64-pin MLF Power Groups Frequency/Functionality Table Byte 0, bit 2 (100_133M# Latch) Byte 0, bit 1 FSB Byte 0, bit 0 FSA Input MHz 1 0 1 0 0 0 1 1 1 0 1 0 0 0 0 1 0 0 1 1 0 100.00 133.33 166.67 200.00 266.67 333.33 400.00 1 1 1 DIF_x MHz 100.00 133.33 166.67 200.00 266.67 333.33 400.00 Reserved Notes 1 1 2 2 2 2 2 Pin Number VDD GND 23 22 29 26 11,17,37,49, 64 10, 38 Description Main PLL, Analog Input buffers DIF clocks Power Down Functionality INPUTS CKPWRGD/PD# 1 0 Input Running X OUTPUTS DIF_x Running Hi-Z PLL State ON OFF SMBus Address Selection (pins 57, 58) SMB_A1 SMB_A0 Address 0 0 D4 0 1 D6 1 0 D8 1 1 DA Notes:100M_133M# 1. Latch selects between 100 and 133 MHz. This is equivalent to FSC in CK410B+/CK509B FS table. 2. Writing Byte 2 bits (2:0) can select other frequencies. These frequencies are not characterized in PLL Mode HIBW_BYPM_LOBW# Selection (Pin 54) State Voltage Mode Low <0.8V Low BW Mid 1.2<Vin<1.8V Bypass High Vin > 2.0V High BW IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 2 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Pin Description PIN # PIN NAME TYPE 1 OE9# 2 DIF_9 DIF_9# OUT OUT 4 OE10# IN 5 6 DIF_10 DIF_10# 7 OE11# IN OUT OUT IN 8 9 10 11 12 13 DIF_11 DIF_11# GND VDD DIF_12 DIF_12# OUT OUT PWR PWR OUT OUT 14 OE12# 15 16 17 DIF_13 DIF_13# VDD 18 OE13_14# 19 20 DIF_14 DIF_14# 21 IREF OUT 22 23 24 25 26 27 28 29 GNDA VDDA CLKA_IN CLKA_IN# GND CLKB_IN CLKB_IN# VDD PWR PWR IN IN PWR IN IN PWR 30 OE_01234# 31 32 33 34 35 36 37 38 39 40 DIF_0 DIF_0# DIF_1 DIF_1# DIF_2 DIF_2# VDD GND DIF_3 DIF_3# IN OUT OUT PWR IN OUT OUT IN OUT OUT OUT OUT OUT OUT PWR PWR OUT OUT DESCRIPTION Active low input for enabling DIF pair 9. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Active low input for enabling DIF pair 10. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Active low input for enabling DIF pair 11. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Ground pin. Power supply, nominal 3.3V 0.7V differential true clock output 0.7V differential complement clock output Active low input for enabling DIF pair 12. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Power supply, nominal 3.3V Active low input for enabling DIF pairs 13 and 14 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output This pin establishes the reference current for the differential current-mode output pairs. This pin requires a fixed precision resistor tied to ground in order to establish the appropriate current. 475 ohms is the standard value. Ground pin for the PLL core. 3.3V power for the PLL core. True Input for differential reference clock. Complement Input for differential reference clock. Ground pin. True Input for differential reference clock. Complement Input for differential reference clock. Power supply, nominal 3.3V Active low input for enabling DIF pairs 0, 1, 2, 3 and 4. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output 0.7V differential true clock output 0.7V differential complement clock output 0.7V differential true clock output 0.7V differential complement clock output Power supply, nominal 3.3V Ground pin. 0.7V differential true clock output 0.7V differential complement clock output IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 3 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Pin Description (continued) 41 42 DIF_4 DIF_4# 43 OE5# 44 45 DIF_5 DIF_5# 46 OE6# 47 48 49 DIF_6 DIF_6# VDD OUT OUT IN OUT OUT IN OUT OUT PWR 50 OE7# 51 52 53 DIF_7 DIF_7# 100M_133M# IN 54 HIBW_BYPM_LOBW# IN 55 56 57 58 SMBCLK SMBDAT SMB_A1 SMB_A0 IN I/O IN IN 59 SEL_A_B# IN 60 61 62 CKPWRGD/PD# DIF_8 DIF_8# 63 OE8# IN 64 VDD PWR OUT OUT IN IN OUT OUT 0.7V differential true clock output 0.7V differential complement clock output Active low input for enabling DIF pair 5. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Active low input for enabling DIF pair 6. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Power supply, nominal 3.3V Active low input for enabling DIF pair 7. 1 = tri-state outputs, 0 = enable outputs 0.7V differential true clock output 0.7V differential complement clock output Input to select operating frequency. See Frequency/Functionality Table for functionality of this pin. Trilevel input to select High BW, Bypass Mode or Low BW. 0 = Low BW Mode, Mid= Bypass Mode, 1 = High Bandwidth Clock pin of SMBUS circuitry, 5V tolerant Data pin of SMBUS circuitry, 5V tolerant SMBus address bit 1 SMBus address bit 0 (LSB) Input to select differential input clock A or differential input clock B. 0 = Input B selected, 1 = Input A selected. Notifies the clock to sample latched inputs on the rising edge, and to power down on the falling edge. 0.7V differential true clock output 0.7V differential complement clock output Active low input for enabling DIF pair 8. 1 = tri-state outputs, 0 = enable outputs Power supply, nominal 3.3V IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 4 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Electrical Characteristics - Absolute Maximum Ratings PARAMETER 3.3V Core Supply Voltage 3.3V Logic Supply Voltage Input Low Voltage Input High Voltage Input High Voltage SYMBOL VDDA VDD VIL VIH VIHSMB Storage Temperature Junction Temperature Input ESD protection Ts Tj ESD prot CONDITIONS MIN TYP GND-0.5 Except for SMBus interface SMBus clock and data pins -65 Human Body Model 2000 MAX 4.6 4.6 UNITS NOTES V 1,2 V 1,2 V 1 VDD+0.5V V 1 5.5V V 1 ° 1 150 C 125 °C 1 V 1 1 Guaranteed by design and characterization, not 100% tested in production. 2 Operation under these conditions is neither implied nor guaranteed. Electrical Characteristics - Clock Input Parameters TA = TCOM or TIND; Supply Voltage VDD/VDDA = 3.3 V +/-5%, See Test Loads for Loading Conditions PARAMETER SYMBOL Input High Voltage - DIF_IN VIHDIF Input Low Voltage - DIF_IN VILDIF CONDITIONS Differential inputs (single-ended measurement) Differential inputs (single-ended measurement) MIN TYP MAX UNITS NOTES 600 800 1150 mV 1 VSS - 300 0 300 mV 1 Input Common Mode Voltage - DIF_IN Input Amplitude - DIF_IN Input Slew Rate - DIF_IN Input Leakage Current VCOM Common Mode Input Voltage 300 400 1000 mV 1 VSWING dv/dt IIN Peak to Peak value Measured differentially VIN = VDD , VIN = GND 300 0.4 -5 750 2 1450 8 5 mV V/ns uA 1 1,2 1 Input Duty Cycle dtin Measurement from differential wavefrom 45 50 55 % 1 Input Jitter - Cycle to Cycle J DIFIn Differential Measurement 0 50 125 ps 1 1 2 Guaranteed by design and characterization, not 100% tested in production. Slew rate measured through +/-75mV window centered around differential zero Electrical Characteristics - Phase Jitter Parameters TA = TCOM or TIND; Supply Voltage VDD/VDDA = 3.3 V +/-5%, See Test Loads for Loading Conditions PARAMETER Phase Jitter, PLL Mode SYMBOL CONDITIONS tjphPCIeG1 PCIe Gen 1 tjphPCIeG2 tjphQPI tjphPCIeG1 Additive Phase Jitter, Bypass mode tjphPCIeG2 tjphQPI MIN PCIe Gen 2 Lo Band 10kHz < f < 1.5MHz PCIe Gen 2 High Band 1.5MHz < f < Nyquist (50MHz) QPI (133MHz, 4.8Gb/s, 6.4Gb/s 12UI) PCIe Gen 1 PCIe Gen 2 Lo Band 10kHz < f < 1.5MHz PCIe Gen 2 High Band 1.5MHz < f < Nyquist (50MHz) QPI (133MHz, 4.8Gb/s, 6.4Gb/s 12UI) TYP MAX 32/42 86 1.2/1.5 3 2.1/2.7 3.1 0.25/0.28 0.5 2 10 0.0 0.3 0.30 0.5 0.25 0.4 UNITS Notes ps 1,2,3,4 (p-p) ps 1,2,4 (rms) ps 1,2,4 (rms) ps 1,4,5 (rms) ps 1,2,3 (p-p) ps 1,2,6 (rms) ps 1,2,6 (rms) ps 1,5,6 (rms) 1 Applies to all outputs. Device driven by IDT CK410B+ (932S421CGLF) or equivalent See http://www.pcisig.com for complete specs 3 Sample size of at least 100K cycles. This figures extrapolates to 108ps pk-pk @ 1M cycles for a BER of 1-12. 4 First number is Low BW, second number is Hi BW. 5 Calculated from Intel-supplied Clock Jitter Tool v 1.6.4, with 7.8M rolloff 6 For RMS figures, additive jitter is calculated by solving the following equation: (Additive jitter)^2 = (total jittter)^2 - (input jitter)^2 2 IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 5 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Electrical Characteristics - Input/Supply/Common Parameters TA = TCOM or TIND; Supply Voltage VDD/VDDA = 3.3 V +/-5%, See Test Loads for Loading Conditions PARAMETER SYMBOL Ambient Operating Temperature TCOM TIND Input High Voltage VIH Input Low Voltage VIL I IN Input Current I INP Input Frequency Pin Inductance Fibyp Fipll Fipll Lpin CIN CONDITIONS TYP MAX 25 25 70 85 °C °C 1 1 2.400 VDD + 0.3 V 1 0.400 0.8 V 1 5 uA 1 200 uA 1 400 110 150 7 5 2.7 MHz MHz MHz nH pF pF 2 2 2 1 1 1,4 6 pF 1 1 ms 1,2 33 kHz 1 10 12 clocks 1,3 0.2 300 us 1,3 0.4 5 5 0.8 ns ns V 1,2 1,2 1 2.1 2.4 VDDSMB V 1 0.3 5 3.3 0.4 4 2.7 5.5 1000 300 V mA V ns ns 1 1 1 1 1 100 kHz 1,5 Commmercial range 0 Industrial range -40 Single-ended inputs, except SMBus, 2 low threshold and tri-level inputs Single-ended inputs, except SMBus, GND - 0.3 low threshold and tri-level inputs Single-ended inputs, VIN = GND, V IN = -5 VDD Single-ended inputs V IN = 0 V; Inputs with internal pull-up -200 resistors VIN = VDD; Inputs with internal pulldown resistors VDD = 3.3 V, Bypass mode 33 VDD = 3.3 V, 100MHz PLL mode 80 VDD = 3.3 V, 133.33MHz PLL mode 120 CINDIF_IN Logic Inputs, except DIF_IN DIF_IN differential clock inputs COUT Output pin capacitance Clk Stabilization TSTAB From VDD Power-Up and after input clock stabilization or de-assertion of PD# to 1st clock Input SS Modulation Frequency f MODIN Allowable Frequency (Triangular Modulation) OE# Latency tLATOE# Tdrive_PD# t DRVPD Tfall Trise SMBus Input Low Voltage tF tR V ILSMB SMBus Input High Voltage V IHSMB SMBus Output Low Voltage SMBus Sink Current Nominal Bus Voltage SCLK/SDATA Rise Time SCLK/SDATA Fall Time SMBus Operating Frequency VOLSMB IPULLUP VDDSMB t RSMB t FSMB @ I PULLUP @ V OL 3V to 5V +/- 10% (Max VIL - 0.15) to (Min VIH + 0.15) (Min VIH + 0.15) to (Max VIL - 0.15) f MAXSMB Maximum SMBus operating frequency Capacitance MIN DIF start after OE# assertion DIF stop after OE# deassertion DIF output enable after PD# de-assertion Fall time of control inputs Rise time of control inputs 100.00 133.33 1.5 1.5 0.5 30 4 400 UNITS NOTES 1 Guaranteed by design and characterization, not 100% tested in production. Control input must be monotonic from 20% to 80% of input swing. 3 Time from deassertion until outputs are >200 mV 4 DIF_IN input 2 5 The differential input clock must be running for the SMBus to be active. Tested at Fin=100MHz. IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 6 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Electrical Characteristics - DIF 0.7V Current Mode Differential Outputs TA = TCOM or TIND; Supply Voltage VDD/VDDA = 3.3 V +/-5%, See Test Loads for Loading Conditions PARAMETER SYMBOL CONDITIONS MIN TYP MAX Slew rate Trf 1 2.2 4 V/ns 1, 2, 3 Slew rate matching ΔTrf Scope averaging on Slew rate matching, Scope averaging on 11 20 % 1, 2, 4 Voltage High VHigh 660 772 850 Voltage Low VLow Statistical measurement on singleended signal using oscilloscope math function. (Scope averaging on) Max Voltage Min Voltage Vswing Crossing Voltage (abs) Crossing Voltage (var) Vmax Vmin Vswing Vcross_abs Δ-Vcross Measurement on single ended signal using absolute value. (Scope averaging Scope averaging off Scope averaging off Scope averaging off UNITS NOTES 1 mV -150 10 150 870 -47 1390 360 14 1150 -300 300 250 1 mV 1 1 1, 2 1, 5 1, 6 mV 550 mV 140 mV 1 Ω Guaranteed by design and characterization, not 100% tested in production. IREF = VDD/(3xRR). For RR = 475 (1%), IREF = 2.32mA. IOH = 6 x I REF and VOH = 0.7V @ ZO=50Ω (100Ω differential impedance). 2 Measured from differential waveform 3 Slew rate is measured through the Vswing voltage range centered around differential 0V. This results in a +/-150mV window around differential 0V. 4 Matching applies to rising edge rate of Clock / falling edge rate of Clock#. It is measured in a +/-75mV window centered on the average cross point where Clock rising meets Clock# falling. The median cross point is used to calculate the voltage thresholds the oscilloscope uses for the edge rate calculations. 5 Vcross is defined as voltage where Clock = Clock# measured on a component test board and only applies to the differential rising edge (i.e. Clock rising and Clock# falling). 6 The total variation of all Vcross measurements in any system. Note that this is a subset of V_cross_min/max (V_cross absolute) allowed. The intent is to limit Vcross induced modulation by setting V_cross_delta to be smaller than V_cross absolute. Electrical Characteristics - Current Consumption TA = TCOM or TIND; Supply Voltage VDD/VDDA = 3.3 V +/-5%, See Test Loads for Loading Conditions PARAMETER TYP MAX TA - TCOM, All outputs active <200MHz 306 330 mA 1 IDD3.3VDDOP TA - TCOM, All outputs active >=200MHz 360 390 mA 1 IDD3.3VDDAOP TA - TCOM, All outputs active <200MHz 29 36 mA 1 IDD3.3VDDAOP TA - TCOM, All outputs active >=200MHz 29 36 mA 1 VDD Powerdown Current, Commerical Temp IDD3.3VDDPDZ TA = TCOM, All differential pairs Hi-Z 12 15 mA 1 VDDA Powerdown Current, Commercial Temp IDD3.3VDDAPDZ TA = TCOM, All differential pairs Hi-Z 15 20 mA 1 IDD3.3VDDOP TA - TIND, All outputs active <200MHz 325 350 mA 1 IDD3.3VDDAOP TA - TIND, All outputs active >=200MHz 390 420 mA 1 IDD3.3VDDOP TA - TIND, All outputs active >=200MHz 33 40 mA 1 IDD3.3VDDAOP TA - TIND, All outputs active >=200MHz 33 40 mA 1 VDD Powerdown Current, Industrial Temp IDD3.3VDDPDZ TA = TIND, All differential pairs Hi-Z 15 20 mA 1 VDDA Powerdown Current, Industrial Temp IDD3.3VDDAPDZ TA = TIND, All differential pairs Hi-Z 16 20 mA 1 VDD Operating Current, Commerical Temp VDDA Operating Current, Commercial Temp VDD Operating Current, Industrial Temp VDDA Operating Current, Industrial Temp SYMBOL CONDITIONS IDD3.3VDDOP MIN UNITS NOTES 1 Guaranteed by design and characterization, not 100% tested in production. IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 7 1578—01/18/11 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Electrical Characteristics - Skew and Differential Jitter Parameters TA = TCOM or TIND; Supply Voltage VDD/VDDA = 3.3 V +/-5%, See Test Loads for Loading Conditions PARAMETER SYMBOL CLK_IN, DIF[x:0], 100M t SPO_PLL100M CLK_IN, DIF[x:0], 133M t SPO_PLL133M CLK_IN, DIF[x:0] t PD_BYP CLK_IN, DIF[x:0] tDSPO_PLL CLK_IN, DIF[x:0] t DSPO_BYP CLK_IN, DIF[x:0] t DTE CLK_IN, DIF[x:0] t DSSTE DIF{x:0] t SKEW_ALL PLL Jitter Peaking PLL Jitter Peaking PLL Bandwidth PLL Bandwidth Duty Cycle jpeak-hibw jpeak-lobw pllHIBW pllLOBW t DC Duty Cycle Distortion t DCD Jitter, Cycle to cycle t jcyc-cyc CONDITIONS Input-to-Output Skew in PLL mode nominal value @ 25°C, 3.3V Input-to-Output Skew in PLL mode nominal value @ 25°C, 3.3V Input-to-Output Skew in Bypass mode nominal value @ 25°C, 3.3V Input-to-Output Skew Varation in PLL mode across voltage and temperature Input-to-Output Skew Varation in Bypass mode across voltage and temperature Random Differential Tracking error beween two 9EX2 devices in Hi BW Mode Random Differential Spread Spectrum Tracking error beween two 9EX2 devices in Hi BW Mode Output-to-Output Skew across all outputs (Common to Bypass and PLL mode) High Bandwidth Low Bandwidth High Bandwidth Low Bandwidth Measured differentially, PLL Mode Measured differentially, Bypass Mode @100MHz PLL mode Additive Jitter in Bypass Mode MIN TYP MAX UNITS NOTES 925 1019 1125 ps 1,2,4,5,8 1100 1120 1200 ps 1,2,4,5,8 4 4.6 5.2 ns 1,2,3,5,8 |258| |350| ps 1,2,3,5,6 ,8 |771| |900| ps 1,2,3,5,6 ,8 2 10 20 75 ps 1,2,3,5,8 ,13 75 150 ps 1,2,8 0 0 2 0.7 45 2.3 2.5 2.5 0.87 49.6 3 3 4 1.4 55 dB dB MHz MHz % 7,8 7,8 8,9 8,9 1 -2 0.2 2 % 1,10 27 20 50 50 ps ps 1 1 ps 1,2,3,5,8 (rms) ,12 Notes for preceding table: Measured into fixed 2 pF load cap. Input to output skew is measured at the first output edge following the corresponding input. 1 2 Measured from differential cross-point to differential cross-point. 3 All Bypass Mode Input-to-Output specs refer to the timing between an input edge and the specific output edge created by it. 4 This parameter is deterministic for a given device 5 Measured with scope averaging on to find mean value. 6. Long-term variation from nominal of input-to-output skew over temperature and voltage for a single device. 7 Measured as maximum pass band gain. At frequencies within the loop BW, highest point of magnification is called PLL jitter peaking. 8. Guaranteed by design and characterization, not 100% tested in production. 9 Measured at 3 db down or half power point. 10 Duty cycle distortion is the difference in duty cycle between the output and the input clock when the device is operated in bypass mod 11 Measured from differential waveform 12. This parameter is measured at the outputs of two separate ICS9EX21501 devices driven by a single CK410B+. The ICS9EX21501's must be set to high bandwidth. Differential phase jitter is the accumulation of the phase jitter not shared by the outputs (eg. not including the affects of spread spectrum). Target ranges of consideration are agents with BW of 1-22Mhz and 11-33Mhz. 13 Differential spread spectrum tracking error is the difference in spread spectrum tracking between two ICS9EX21501 devices This parameter is measured at the outputs of two separate ICS9EX21501 devices driven by a single CK410B+ in Spread Spectrum mode. The ICS9EX21501's must be set to high bandwidth. The spread spectrum characteristics are: maximum of 0.5%, 30-33KHz modulation frequency, triangle profile. IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 8 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet HCSL Differential Output Test Load Zo= differential impedance Rs 2pF Rs Rp HCSL Output 2pF Rp Differential Output Termination Table DIF Zo (Ω) Iref (Ω) 100 85 475 412 Rs (Ω) Rp (Ω) CL (pF) 33 27 50 43.2 2 2 Test Load IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 9 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet General SMBus serial interface information for the 9EX21501 How to Write: How to Read: Controller (host) sends a start bit. Controller (host) sends the write address D4 (H) ICS clock will acknowledge Controller (host) sends the beginning byte location = N ICS clock will acknowledge Controller (host) sends the data byte count = X ICS clock will acknowledge Controller (host) starts sending Byte N through Byte N + X -1 • ICS clock will acknowledge each byte one at a time • Controller (host) sends a Stop bit • • • • • • • • • • • • • • • • • • • • • • Index Block Write Operation Controlle r (Host) starT bit T Slave Address D4(H ) W Rite WR Controller (host) will send start bit. Controller (host) sends the write address D4 (H) ICS clock will acknowledge Controller (host) sends the begining byte location = N ICS clock will acknowledge Controller (host) will send a separate start bit. Controller (host) sends the read address D5 (H) ICS clock will acknowledge ICS clock will send the data byte count = X ICS clock sends Byte N + X -1 ICS clock sends Byte 0 through byte X (if X(H) was written to byte 8). Controller (host) will need to acknowledge each byte Controller (host) will send a not acknowledge bit Controller (host) will send a stop bit Index Block Read Operation Controlle r (Host) T starT bit Slave Address D4(H ) WR W Rite ICS (Sla ve /Re ce ive r) ICS (Sla ve /Re ce ive r) ACK ACK Beginning Byte = N Beginning Byte = N ACK ACK Data Byte Count = X RT Repeat starT Slave Address D5(H ) RD ReaD ACK Beginning Byte N ACK X Byte ACK Data Byte Count = X ACK Beginning Byte N Byte N + X - 1 ACK X Byte ACK P stoP bit Byte N + X - 1 Note: SMBus address is selectable among 4 addresses. See tabel on page 2. N P IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Not acknowledge stoP bit 1578—01/18/11 10 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet 9EX21501 SMBus Addressing SMB_A(2:0) = 000 SMB Adr: D0 (DB1200G/GS) (DB1900G/GS) SMB_A(2:0) = 001 SMB Adr: D2 (DB1200G/GS) (DB1900G/GS) SMB_A(1:0) = 00 SMB Adr: D4 OR SMB_A(2:0) = 010 SMB Adr: D4 (DB1200G/GS) (DB1900G/GS) OR SMB_A(2:0) = 011 SMB Adr: D6 (DB1200G/GS) ` (DB1900G/GS) OR SMB_A(2:0) = 100 SMB Adr: D8 (DB1200G/GS) (DB1900G/GS) OR SMB_A(2:0) = 101 SMB Adr: DA (DB1200G/GS) (DB1900G/GS) 9EX21501 SMB_A(1:0) = 01 SMB Adr: D6 9EX21501 SMB_A(1:0) = 10 SMB Adr: D8 9EX21501 SMB_A(1:0) = 11 SMB Adr: DA 9EX21501 SMB_A(2:0) = 110 SMB Adr: DC (DB1200G/GS) (DB1900G/GS) SMB Adr: D2 OR (CK410B+/CK509B) OR SMB Adr: DC 9DB403/803 (DB400E/800E) SMB_A(2:0) = 111 SMB Adr: DE (DB1200G/GS) (DB1900G/GS) IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 11 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet SMBusTable: Output, and PLL BW Control Register Pin # Name Control Function Byte 0 Type PLL_BW# adjust RW BYPASS# test mode / PLL RW Bit 7 54 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 DIF_14 - 100M_133M# FSB FSA RESERVED Output Control RESERVED Frequency Select Bit C Frequency Select Bit B Frequency Select bit A RW RW RW RW 0 1 00 = Low BW (1MHz) 10 = Bypass 11 = High BW (3MHz) Hi-Z Enable 133MHz 100MHz See Frequency Select Table Default Latch Latch 1 1 0 Latch 0 1 SMBusTable: Output Control Register Pin # Name Byte 1 Bit 7 DIF_6 Bit 6 DIF_5 Bit 5 DIF_4 Bit 4 DIF_3 Bit 3 DIF_2 Bit 2 DIF_1 Bit 1 DIF_0 Bit 0 Control Function RESERVED Output Control Output Control Output Control Output Control Output Control Output Control Output Control Type 0 1 RW RW RW RW RW RW RW Hi-Z Hi-Z Hi-Z Hi-Z Hi-Z Hi-Z Hi-Z Enable Enable Enable Enable Enable Enable Enable SMBusTable: Output Control Register Byte 2 Pin # Name DIF_13 Bit 7 Bit 6 DIF_12 Bit 5 DIF_11 Bit 4 DIF_10 Bit 3 DIF_9 Bit 2 Control Function Output Control RESERVED Output Control Output Control Output Control Output Control Type RW 0 Hi-Z 1 Enable RW RW RW RW Hi-Z Hi-Z Hi-Z Hi-Z Enable Enable Enable Enable Default 1 1 1 1 1 1 Default 1 1 1 1 1 1 1 1 Bit 1 DIF_8 Output Control RW Hi-Z Enable 1 Bit 0 DIF_7 Output Control RW Hi-Z Enable 1 Type R R R R 0 Pin Low Pin Low Pin Low Pin Low 1 Pin Hi Pin Hi Pin Hi Pin Hi R R R Pin Low Pin Low Pin Low Pin Hi Pin Hi Pin Hi Default X X X X 1 X X X SMBusTable: Output Enable Readback Register Pin # Name Control Function Byte 3 OE10# Input Pin Readback 4 Bit 7 1 OE9# Input Pin Readback Bit 6 63 OE8# Input Pin Readback Bit 5 50 OE7# Input Pin Readback Bit 4 RESERVED Bit 3 46 OE6# Input Pin Readback Bit 2 43 OE5# Input Pin Readback Bit 1 30 OE_01234# Input Pin Readback Bit 0 IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 12 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet SMBusTable: Output Enable Readback Register Byte 4 Pin # Name Control Function RESERVED Bit 7 RESERVED Bit 6 100M_133M# Input Pin Readback Bit 5 SEL_A_B# Input Pin Readback Bit 4 OE13_14# Input Pin Readback 18 Bit 3 RESERVED Bit 2 14 OE12# Input Pin Readback Bit 1 7 OE11# Input Pin Readback Bit 0 Type 0 1 R R R 133M Input B Pin Low 100M Input A Pin Hi R R Pin Low Pin Low Pin Hi Pin Hi Default 0 0 X X X 1 X X Note: For an output to be enabled, BOTH the Output Enable Bit and the OE# pin must be enabled. This means that the Output Enable Bit must be '1' and the corresponding OE# pin must be '0'. SMBusTable: Vendor & Revision ID Register Byte 5 Pin # Name Control Function RID3 Bit 7 RID2 Bit 6 REVISION ID RID1 Bit 5 RID0 Bit 4 VID3 Bit 3 VID2 Bit 2 VENDOR ID VID1 Bit 1 VID0 Bit 0 Type R R R R R R R R 0 - 1 - Default 0 0 0 1 0 0 0 1 SMBusTable: DEVICE ID Byte 6 Pin # Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 Type R R R R R R R R 0 1 Default 0 0 0 1 1 0 0 0 Name Control Function Device ID 7 (MSB) Device ID 6 Device ID 5 Device ID 4 Device ID 3 Device ID 2 Device ID 1 Device ID 0 SMBusTable: Byte Count Register Byte 7 Pin # Name BC7 Bit 7 BC6 Bit 6 BC5 Bit 5 BC4 Bit 4 BC3 Bit 3 BC2 Bit 2 BC1 Bit 1 BC0 Bit 0 Control Function Writing to this register configures how many bytes will be read back. IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Type RW RW RW RW RW RW RW RW Device ID is 18 hex 0 - 1 - Default 0 0 0 0 0 1 1 1 1578—01/18/11 13 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet THERMALLY ENHANCED, VERY THIN, FINE PITCH QUAD FLAT / NO LEAD PLASTIC PACKAGE DIMENSIONS N ND NE DIMENSIONS (mm) SYMBOL A A1 A3 b e D x E BASIC D2 MIN. / MAX. E2 MIN. / MAX. L MIN. / MAX. 64 16 16 MIN. MAX. 0.8 1.0 0 0.05 0.25 Reference 0.18 0.3 0.50 BASIC 9.00 x 9.00 7.00 7.25 7.00 7.25 0.30 0.50 Ordering Information Part / Order Number 9EX21501AKLF 9EX21501AKLFT 9EX21501AKILF 9EX21501AKILFT Shipping Packaging Trays Tape and Reel Trays Tape and Reel Package 64-pin MLF 64-pin MLF 64-pin MLF 64-pin MLF Temperature 0 to +70° C 0 to +70° C -40 to +85°C -40 to +85°C "LF” suffix to the part number are the Pb-free configuration and are RoHS compliant. "A" is the revision designator (will not correlate with datasheet revision). Due to package size constraints actual top side marking may differ from the full orderable part number. IDT® 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux 1578—01/18/11 14 9EX21501 15 Output PCIe G2/QPI Differential Buffer with 2:1 Input Mux Datasheet Revision History Rev. 0.1 0.2 0.3 0.4 0.5 Who Issue Date Description RDW 4/6/2009 Initial Release 1. Lowered IDD 2. Updated block diagram to correct typo's 3. Corrected Pin descriptions 4. Corrected Frequency/functionality table references to Byte 2, should be RDW 4/7/2008 Byte 0 5. Updated Power Groups Table 6. Corrected typo in SMBus Address Selection Table. 7. Corrected references to 9EX1501 to be 9EX21501 1. Added more detailed Idd numbers to DS RDW 11/24/2009 2. Added industrial temp Idd numbers and ordering information 1.Corrected Pin Description for Pin 52. There was descrepancy between the Frequency/Functionality Table and the Pin Description. The Pin RDW 2/4/2010 Description was not correct. Instead of the pin description defining functionality, it now refers to the Frequency Functionality Table for the definition. 1. Reformatted Electrical Tables to latest template 2. Updated electrical tables with characterized data RDW 1/18/2011 3. Added Test loads diagram and table 4. Move to Final Page # - Various 4 Various Innovate with IDT and accelerate your future networks. Contact: www.IDT.com For Sales For Tech Support 800-345-7015 408-284-8200 Fax: 408-284-2775 408-284-6578 [email protected] Corporate Headquarters Asia Pacific and Japan Europe Integrated Device Technology, Inc. 6024 Silver Creek Valley Road San Jose, CA 95138 United States 800 345 7015 +408 284 8200 (outside U.S.) IDT Singapore Pte. Ltd. 1 Kallang Sector #07-01/06 KolamAyer Industrial Park Singapore 349276 Phone: 65-6-744-3356 Fax: 65-6-744-1764 IDT Europe Limited 321 Kingston Road Leatherhead, Surrey KT22 7TU England Phone: 44-1372-363339 Fax: 44-1372-378851 © 2011 Integrated Device Technology, Inc. All rights reserved. Product specifications subject to change without notice. IDT, ICS, and the IDT logo are trademarks of Integrated Device Technology, Inc. Accelerated Thinking is a service mark of Integrated Device Technology, Inc. All other brands, product names and marks are or may be trademarks or registered trademarks used to identify products or services of their respective owners. Printed in USA 15