Differential Clock/Data Multiplexer ICS831721I DATA SHEET General Description Features The ICS831721I is a high-performance, differential HCSL clock/data multiplexer and fanout buffer. The device is designed for the multiplexing of high-frequency clock and data signals. The device has two differential, selectable clock/data inputs. The selected input signal is output at one differential HCSL output. Each input pair accepts HCSL, LVDS, and LVPECL levels. The ICS831721I is characterized to operate from a 3.3V power supply. Guaranteed input, output-to-output and part-to-part skew characteristics make the ICS831721I ideal for those clock and data distribution applications demanding well-defined performance and repeatability. The ICS831721I supports the clock multiplexing and distribution of PCI Express Generation 1, 2 and 3 clock signals. • • • 2:1 differential clock/data multiplexer with fanout • • • One differential HCSL output • • • • • Input skew: 55ps (maximum) Block Diagram Pulldown CLK1 nCLK1 Pulldown SEL nOE Pullup/down Pullup/down Maximum input/output clock frequency: 700MHz (maximum) Maximum input/output data rate: 1400Mb/s (NRZ)LVCMOS interface levels for all control inputs Part-to-part skew: 400ps (maximum) Full 3.3V supply voltage Available in lead-free (RoHS 6) 16 TSSOP package -40°C to 85°C ambient operating temperature CLK0 nCLK0 VDD CLK1 nCLK1 GND nc VDD 0 Q nQ 1 Pullup AUGUST 19, 2011 1 2 3 4 5 6 7 8 16 15 14 13 12 11 10 9 IREF SEL VDD nQ Q VDD GND nOE ICS831721I 16 Lead TSSOP 4.4mm x 5.0mm x 0.925mm package body G Package Top View Pulldown ICS831721AGI REVISION A Each differential input pair can accept the following levels: HCSL, LVHSTL, LVDS and LVPECL Pin Assignment IREF CLK0 nCLK0 Two selectable, differential inputs 1 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Table 1. Pin Descriptions Number Name Type Description 1 CLK0 Input Pulldown 2 nCLK0 Input Pullup/Pulldown 3, 8, 11, 14 VDD Power 4 CLK1 Input Pulldown 5 nCLK1 Input Pullup/Pulldown 6, 10 GND Power 7 nc Unused 9 nOE Input 12, 13 Q, nQ Output 15 SEL Input 16 IREF Input Non-inverting clock/data input 0. Inverting differential clock input 0. VDD/2 default when left floating. Positive power supply. Non-inverting clock/data input 1. Inverting differential clock input 1. VDD/2 default when left floating. Power supply ground. No connect. Pullup Output enable. See Table 3A for function. LVCMOS/LVTTL interface levels. Differential output pair. HCSL interface levels. Pulldown Input select. See Table 3B for function. LVCMOS/LVTTL interface levels. An external fixed precision resistor (475Ω) from this pin to ground provides a reference current used for the differential current-mode Q, nQ outputs. NOTE: Pullup and pulldown refer to internal input resistors. See Table 2, Pin Characteristics, for typical values. Table 2. Pin Characteristics Symbol Parameter Test Conditions Minimum Typical Maximum Units CIN Input Capacitance 4 pF RPULLDOWN Input Pulldown Resistor 51 kΩ RPULLUP Input Pulldown Resistor 51 kΩ Function Tables Table 3A. nOE Configuration Table Input nOE 0 1 (default) Operation Output Q, nQ is enabled. Output Q, nQ is in a high-impedance state. NOTE: nOE is an asynchronous control. Table 3B. SEL Configuration Table Input SEL Selected Input 0 (default) CLK0, nCLK0 1 CLK1, nCLK1 NOTE: SEL is an asynchronous control. ICS831721AGI REVISION A AUGUST 19, 2011 2 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Absolute Maximum Ratings NOTE: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These ratings are stress specifications only. Functional operation of product at these conditions or any conditions beyond those listed in the DC Characteristics or AC Characteristics is not implied. Exposure to absolute maximum rating conditions for extended periods may affect product reliability. Item Rating Supply Voltage, VDD 4.6V Inputs, VI -0.5V to VDD + 0.5V Outputs, VO -0.5V to VDD + 0.5V Package Thermal Impedance, θJA 100.3°C/W (0 mps) Storage Temperature, TSTG -65°C to 150°C DC Electrical Characteristics Table 4A. Power Supply DC Characteristics, VDD = 3.3V ± 0.3V, TA = -40°C to 85°C Symbol Parameter Test Conditions VDD Positive Supply Voltage IDD Power Supply Current Minimum Typical Maximum Units 3.0 3.3 3.6 V 26 mA Maximum Units Table 4B. LVCMOS/LVTTL Input DC Characteristics, VDD = 3.3V ± 0.3V, TA = -40°C to 85°C Symbol Parameter Test Conditions Minimum Typical VIH Input High Voltage 2 VDD + 0.3 V VIL Input Low Voltage -0.3 0.8 V IIH Input High Current IIL Input Low Current nOE VDD = VIN = 3.6V 5 µA SEL VDD = VIN = 3.6V 150 µA nOE VDD = 3.6V, VIN = 0V -150 µA SEL VDD = 3.6V, VIN = 0V -5 µA Table 4C. Differential DC Characteristics, VDD = 3.3V ± 0.3V, TA = -40°C to 85°C Symbol Parameter Test Conditions Minimum IIH Input High Current CLK0, nCLK0, CLK1, nCLK1 Input Low Current CLK0, CLK1 VDD = 3.6V, VIN = 0V -5 µA IIL nCLK0, nCLK1 VDD = 3.6V, VIN = 0V -150 µA VPP Peak-to-Peak Voltage; NOTE 1 0.15 1.3 V VCMR Common Mode Input Voltage; NOTE 1, 2 0.5 VDD – 0.85 V VDD = VIN = 3.6V Typical Maximum Units 150 µA NOTE 1: VIL should not be less than -0.3V. NOTE 2: Common mode input voltage is defined as VIH. ICS831721AGI REVISION A AUGUST 19, 2011 3 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Table 5. PCI Express Jitter Specifications, VDD = 3.3V ± 0.3V, TA= -40°C to 85°C Parameter Symbol tJ (PCIe Gen 1) Phase Jitter Peak-to-Peak NOTE 1, 4 tREFCLK_HF_RMS (PCIe Gen 2) Test Conditions Minimum Typical Maximum PCIe Industry Specification Units ƒ = 100MHz, Evaluation Band: 0Hz - Nyquist (clock requency/2) 6.77 11.2 86 ps Phase Jitter RMS; NOTE 2, 4 ƒ = 100MHz, High Band:1.5Hz - Nyquist (clock requency/2) 0.59 1.01 3.1 ps tREFCLK_LF_RMS (PCIe Gen 2) Phase Jitter RMS; NOTE 2, 4 ƒ = 100MHz, Low Band: 10kHz - 1.5Hz 0.03 0.07 3.0 ps tREFCLK_RMS (PCIe Gen 3) Phase Jitter RMS; NOTE 3, 4 ƒ = 100MHz, Evaluation Band: 0Hz - Nyquist (clock requency/2) 0.112 0.185 0.8 ps NOTE: The source generator used in the PCI Express Jitter measurements is Stanford Research Systems CG635 2.0GHz Synthesized Clock Generator. NOTE: Electrical parameters are guaranteed over the specified ambient operating temperature range, which is established when the device is mounted in a test socket with maintained transverse airflow greater than 500 lfpm. The device will meet specifications after thermal equilibrium has been reached under these conditions. For additional information, refer to the PCI Express Application Note section in the datasheet. NOTE 1: Peak-to-Peak jitter after applying system transfer function for the Common Clock Architecture. Maximum limit for PCI Express Gen 1 is 86ps peak-to-peak for a sample size of 106 clock periods. NOTE 2: RMS jitter after applying the two evaluation bands to the two transfer functions defined in the Common Clock Architecture and reporting the worst case results for each evaluation band. Maximum limit for PCI Express Generation 2 is 3.1ps RMS for tREFCLK_HF_RMS (High Band) and 3.0ps RMS for tREFCLK_LF_RMS (Low Band). NOTE 3: RMS jitter after applying system transfer function for the common clock architecture. This specification is based on the PCI Express Base Specification Revision 0.7, October 2009 and is subject to change pending the final release version of the specification. NOTE 4: This parameter is guaranteed by characterization. Not tested in production. ICS831721AGI REVISION A AUGUST 19, 2011 4 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER AC Electrical Characteristics Table 5. HCSL AC Characteristics, VDD = 3.3V ± 0.3V, TA = -40°C to 85°C Symbol Parameter Test Conditions Minimum Typical Maximum Units 700 MHz 0.337 ps 2.4 ns fOUT Output Frequency tjit Buffer Additive Phase Jitter, RMS; refer to Additive Phase Jitter Plot 100MHz, Integration Range: 12kHz – 20MHz tPD Propagation Delay, NOTE 1 Any CLKx, nCLKx to Q, nQ tsk(i) Input Skew; NOTE 2 55 ps tsk(pp) Part-to-Part Skew; NOTE 3, 4 400 ps Edge Rate Rise/Fall Edge Rate; NOTE 5, 6 0.6 4.0 V/ns VRB Ringback Voltage; NOTE 5, 7 -100 100 V VMAX Absolute Max Output Voltage; NOTE 8, 9 1150 mV VMIN Absolute Min Output Voltage; NOTE 8, 10 -300 VCROSS Absolute Crossing Voltage; NOTE 8, 11, 12 250 ∆VCROSS Total Variation of VCROSS over all edges; NOTE 8, 11, 13 odc Output Duty Cycle; NOTE 14 MUXISOL Mux Isolation; NOTE 15 0.314 2 mV 550 mV 140 mV fOUT < 312.5MHz 46 54 % fOUT > 312.5MHz 43 57 % ƒ = 100MHz 80 dB NOTE: Electrical parameters are guaranteed over the specified ambient operating temperature range, which is established when the device is mounted in a test socket with maintained transverse airflow greater than 500 lfpm. The device will meet specifications after thermal equilibrium has been reached under these conditions. NOTE 1: Measured from the differential input cross point to the differential output crossing point. NOTE 2: Defined as skew between input paths on the same device, using the same input signal levels, measured at one specific output at the differential cross points. NOTE 3: This parameter is defined in accordance with JEDEC Standard 65. NOTE 4: Defined as skew between outputs on different devices operating at the same supply voltage and with equal load conditions. Using the same type of inputs on each device, the outputs are measured at the differential cross points. NOTE 5: Measurement taken from differential waveform. NOTE 6: Measurement from -150mV to +150mV on the differential waveform (derived from Q minus nQ). The signal must be monotonic through the measurement region for rise and fall time. The 300mV measurement window is centered on the differential zero crossing. NOTE 7: TSTABLE is the time the differential clock must maintain a minimum ±150mV differential voltage after rising/falling edges before it is allowed to drop back into the VRB ±100 differential range. See Parameter Measurement Information Section. NOTE 8: Measurement taken from single-ended waveform. NOTE 9: Defined as the maximum instantaneous voltage including overshoot. See Parameter Measurement Information Section. NOTE 10: Defined as the minimum instantaneous voltage including undershoot. See Parameter Measurement Information Section. NOTE 11: Measured at crossing point where the instantaneous voltage value of the rising edge of Qx equals the falling edge of nQx. See Parameter Measurement Information Section NOTE 12: Refers to the total variation from the lowest crossing point to the highest, regardless of which edge is crossing. Refers to all crossing points for this measurement. See Parameter Measurement Information Section. NOTE 13: Defined as the total variation of all crossing voltage of rising Q and falling nQ. This is the maximum allowed variance in the VCROSS for any particular system. See Parameter Measurement Information Section. NOTE 14: Input duty cycle must be 50%. NOTE 15: Q, nQ output measured differentially. See MUX Isolation Diagram in Parameter Measurement Information Section. ICS831721AGI REVISION A AUGUST 19, 2011 5 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Additive Phase Jitter The spectral purity in a band at a specific offset from the fundamental compared to the power of the fundamental is called the dBc Phase Noise. This value is normally expressed using a Phase noise plot and is most often the specified plot in many applications. Phase noise is defined as the ratio of the noise power present in a 1Hz band at a specified offset from the fundamental frequency to the power value of the fundamental. This ratio is expressed in decibels (dBm) or a ratio of the power in the 1Hz band to the power in the fundamental. When the required offset is specified, the phase noise is called a dBc value, which simply means dBm at a specified offset from the fundamental. By investigating jitter in the frequency domain, we get a better understanding of its effects on the desired application over the entire time record of the signal. It is mathematically possible to calculate an expected bit error rate given a phase noise plot. SSB Phase Noise dBc/Hz Additive Phase Jitter @ 100MHz 12kHz to 20MHz = 0.314ps (typical) Offset from Carrier Frequency (Hz) As with most timing specifications, phase noise measurements has issues relating to the limitations of the equipment. Often the noise floor of the equipment is higher than the noise floor of the device. This is illustrated above. The device meets the noise floor of what is shown, but can actually be lower. The phase noise is dependent on the input source and measurement equipment. ICS831721AGI REVISION A AUGUST 19, 2011 The source generator is the Rhode & Schwarz SMA 100A Signal Generator 9kHz – 6GHz. Phase noise is measured with the Agilent E5052A Signal source Analyzer. 6 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Parameter Measurement Information 3.3V±0.3V 3.3V±0.3V SCOPE 50Ω VDD VDD 50Ω 33Ω Qx HCSL 49.9Ω 2pF HCSL 50Ω 33Ω IREF GND 50Ω IREF nQx GND 475Ω 49.9Ω 2pF 475Ω 0V This load condition is used for IDD, tsk(pp), tsk(i), tPD and tjit measurements. 0V 3.3V HCSL Output Load AC Test Circuit 3.3V HCSL Output Load AC Test Circuit Spectrum of Output Signal Q MUX selects active input clock signal A0 Amplitude (dB) VDD nCLK[0:1] V Cross Points PP V CMR CLK[0:1] MUX_ISOL = A0 – A1 MUX selects static input A1 GND ƒ (fundamental) Differential Input Level Frequency MUX_ISOLATION Par t 1 nCLK[0:1] nQx CLK[0:1] Qx nQ nQy Par t 2 Qx Q t sk(pp) tPD Propagation Delay ICS831721AGI REVISION A AUGUST 19, 2011 Part-to-Part Skew 7 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Parameter Measurement Information, continued VMAX nQ nQ VCROSS_MAX ∆VCROSS VCROSS_MIN Q Q VMIN Single-ended Measurement Points for Absolute Cross Point/Swing Single-ended Measurement Points for Delta Cross Point TSTABLE Rise Edge Rate VRB Fall Edge Rate +150mV VRB = +100mV 0.0V VRB = -100mV -150mV +150mV 0.0V -150mV Q - nQ Q - nQ VRB TSTABLE Differential Measurement Points for Rise/Fall Edge Rate Differential Measurement Points for Ringback nCLK0 CLK0 nCLK1 CLK1 nQ Q tPD2 tPD1 tsk(i) tsk(i) = |tPD1 - tPD2| Input Skew ICS831721AGI REVISION A AUGUST 19, 2011 8 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Applications Information Recommendations for Unused Input Pins Inputs: LVCMOS Control Pins All control pins have internal pullups and pulldowns; additional resistance is not required but can be added for additional protection. A 1kΩ resistor can be used. CLK/nCLK Inputs For applications not requiring the use of the differential input, both CLK and nCLK can be left floating. Though not required, but for additional protection, a 1kΩ resistor can be tied from CLK to ground. Wiring the Differential Input to Accept Single-Ended Levels Figure 1 shows how a differential input can be wired to accept single ended levels. The reference voltage VREF = VCC/2 is generated by the bias resistors R1 and R2. The bypass capacitor (C1) is used to help filter noise on the DC bias. This bias circuit should be located as close to the input pin as possible. The ratio of R1 and R2 might need to be adjusted to position the VREF in the center of the input voltage swing. For example, if the input clock swing is 2.5V and VCC = 3.3V, R1 and R2 value should be adjusted to set VREF at 1.25V. The values below are for when both the single ended swing and VCC are at the same voltage. This configuration requires that the sum of the output impedance of the driver (Ro) and the series resistance (Rs) equals the transmission line impedance. In addition, matched termination at the input will attenuate the signal in half. This can be done in one of two ways. First, R3 and R4 in parallel should equal the transmission line impedance. For most 50Ω applications, R3 and R4 can be 100Ω. The values of the resistors can be increased to reduce the loading for slower and weaker LVCMOS driver. When using single-ended signaling, the noise rejection benefits of differential signaling are reduced. Even though the differential input can handle full rail LVCMOS signaling, it is recommended that the amplitude be reduced. The datasheet specifies a lower differential amplitude, however this only applies to differential signals. For single-ended applications, the swing can be larger, however VIL cannot be less than -0.3V and VIH cannot be more than VCC + 0.3V. Though some of the recommended components might not be used, the pads should be placed in the layout. They can be utilized for debugging purposes. The datasheet specifications are characterized and guaranteed by using a differential signal. Figure 1. Recommended Schematic for Wiring a Differential Input to Accept Single-ended Levels ICS831721AGI REVISION A AUGUST 19, 2011 9 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER PCI Express Application Note PCI Express jitter analysis methodology models the system response to reference clock jitter. The block diagram below shows the most frequently used Common Clock Architecture in which a copy of the reference clock is provided to both ends of the PCI Express Link. In the jitter analysis, the transmit (Tx) and receive (Rx) serdes PLLs are modeled as well as the phase interpolator in the receiver. These transfer functions are called H1, H2, and H3 respectively. The overall system transfer function at the receiver is: Ht ( s ) = H3 ( s ) × [ H1 ( s ) – H2 ( s ) ] The jitter spectrum seen by the receiver is the result of applying this system transfer function to the clock spectrum X(s) and is: Y ( s ) = X ( s ) × H3 ( s ) × [ H1 ( s ) – H2 ( s ) ] In order to generate time domain jitter numbers, an inverse Fourier Transform is performed on X(s)*H3(s) * [H1(s) - H2(s)]. PCIe Gen 2A Magnitude of Transfer Function PCI Express Common Clock Architecture For PCI Express Gen 1, one transfer function is defined and the evaluation is performed over the entire spectrum: DC to Nyquist (e.g for a 100MHz reference clock: 0Hz – 50MHz) and the jitter result is reported in peak-peak. PCIe Gen 2B Magnitude of Transfer Function For PCI Express Gen 3, one transfer function is defined and the evaluation is performed over the entire spectrum. The transfer function parameters are different from Gen 1 and the jitter result is reported in RMS. PCIe Gen 1 Magnitude of Transfer Function For PCI Express Gen 2, two transfer functions are defined with 2 evaluation ranges and the final jitter number is reported in rms. The two evaluation ranges for PCI Express Gen 2 are 10kHz – 1.5MHz (Low Band) and 1.5MHz – Nyquist (High Band). The plots show the individual transfer functions as well as the overall transfer function Ht. ICS831721AGI REVISION A AUGUST 19, 2011 PCIe Gen 3 Magnitude of Transfer Function For a more thorough overview of PCI Express jitter analysis methodology, please refer to IDT Application Note PCI Express Reference Clock Requirements. 10 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Recommended Termination Figure 3A is the recommended source termination for applications where the driver and receiver will be on a separate PCBs. This termination is the standard for PCI Express™ and HCSL output 0.5" Max Rs 22 to 33 +/-5% types. All traces should be 50Ω impedance single-ended or 100Ω differential. 1-14" 0-0.2" L1 L2 L4 L1 L2 L4 0.5 - 3.5" L5 L5 PCI Expres s PCI Express Connector Driver 0-0.2" L3 PCI Express L3 Add-in Card 49.9 +/- 5% Rt Figure 3A. Recommended Source Termination (where the driver and receiver will be on separate PCBs) Figure 3B is the recommended termination for applications where a point-to-point connection can be used. A point-to-point connection contains both the driver and the receiver on the same PCB. With a matched termination at the receiver, transmission-line reflections will 0.5" Max Rs 0 to 33 L1 be minimized. In addition, a series resistor (Rs) at the driver offers flexibility and can help dampen unwanted reflections. The optional resistor can range from 0Ω to 33Ω. All traces should be 50Ω impedance single-ended or 100Ω differential. 0-18" 0-0.2" L2 L3 L2 L3 0 to 33 L1 PCI Express Driver Rt 49.9 +/- 5% Figure 3B. Recommended Termination (where a point-to-point connection can be used) ICS831721AGI REVISION A AUGUST 19, 2011 11 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Differential Clock Input Interface The CLK /nCLK accepts LVDS, LVPECL, LVHSTL, HCSL and other differential signals. Both signals must meet the VPP and VCMR input requirements. Figures 2A to 2F show interface examples for the CLK/nCLK input driven by the most common driver types. The input interfaces suggested here are examples only. Please consult with the vendor of the driver component to confirm the driver termination requirements. For example, in Figure 2A, the input termination applies for IDT open emitter LVHSTL drivers. If you are using an LVHSTL driver from another vendor, use their termination recommendation. 3.3V 3.3V 3.3V 1.8V Zo = 50Ω *R3 33Ω Zo = 50Ω CLK CLK Zo = 50Ω Zo = 50Ω nCLK R1 50Ω IDT LVHSTL Driver nCLK Differential Input LVHSTL R2 50Ω HCSL *R4 Differential Input 33Ω R1 50Ω R2 50Ω *Optional – R3 and R4 can be 0Ω Figure 2A. CLK/nCLK Input Driven by an IDT Open Emitter LVHSTL Driver Figure 2B. CLK/nCLK Input Driven by a 3.3V HCSL Driver 3.3V 3.3V 3.3V 3.3V 3.3V R3 125 R4 125 Zo = 50Ω CLK Zo = 50Ω CLK Zo = 50Ω nCLK Zo = 50Ω LVPECL nCLK LVPECL R1 84 R1 50Ω Differential Input R2 84 R2 50Ω Differential Input R2 50Ω Figure 2D. CLK/nCLK Input Driven by a 3.3V LVPECL Driver Figure 2C. CLK/nCLK Input Driven by a 3.3V LVPECL Driver 3.3V 3.3V Zo = 50Ω CLK R1 100 Zo = 50Ω LVDS nCLK Differential Input Figure 2E. CLK/nCLK Input Driven by a 3.3V LVDS Driver ICS831721AGI REVISION A AUGUST 19, 2011 12 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Power Considerations This section provides information on power dissipation and junction temperature for the ICS831752I. Equations and example calculations are also provided. 1. Power Dissipation. The total power dissipation for the ICS831752I is the sum of the core power plus the analog power plus the power dissipated in the load(s). The following is the power dissipation for VDD = 3.3V + 0.3V = 3.6V, which gives worst case results. • Power (core)MAX = VDD_MAX * IDD_MAX = 3.6V * 26mA = 93.6mW • Power (outputs)MAX = 46.8mW/Loaded Output Pair Total Power_MAX (3.63V, with all outputs switching) = 93.6mW + 46.8mW = 140.4mW 2. Junction Temperature. Junction temperature, Tj, is the temperature at the junction of the bond wire and bond pad directly affects the reliability of the device. The maximum recommended junction temperature is 125°C. Limiting the internal transistor junction temperature, Tj, to 125°C ensures that the bond wire and bond pad temperature remains below 125°C. The equation for Tj is as follows: Tj = θJA * Pd_total + TA Tj = Junction Temperature θJA = Junction-to-Ambient Thermal Resistance Pd_total = Total Device Power Dissipation (example calculation is in section 1 above) TA = Ambient Temperature In order to calculate junction temperature, the appropriate junction-to-ambient thermal resistance θJA must be used. Assuming no air flow and a multi-layer board, the appropriate value is 100.3°C/W per Table 6 below. Therefore, Tj for an ambient temperature of 85°C with all outputs switching is: 85°C + 0.140W * 100.3°C/W = 99°C. This is below the limit of 125°C. This calculation is only an example. Tj will obviously vary depending on the number of loaded outputs, supply voltage, air flow and the type of board (multi-layer). Table 6. Thermal Resistance θJA for 16 Lead TSSOP, Forced Convection θJA by Velocity Meters per Second Multi-Layer PCB, JEDEC Standard Test Boards ICS831721AGI REVISION A AUGUST 19, 2011 0 1 2.5 100.3°C/W 96.0°C/W 93.9°C/W 13 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER The purpose of this section is to calculate power dissipation on the IC per HCSL output pair. HCSL output driver circuit and termination are shown in Figure 4. VDD IOUT = 17mA ➤ VOUT RREF = 475Ω ± 1% RL 50Ω IC Figure 4. HCSL Driver Circuit and Termination HCSL is a current steering output which sources a maximum of 17mA of current per output. To calculate worst case on-chip power dissipation, use the following equations which assume a 50Ω load to ground. The highest power dissipation occurs when VDD_MAX. Power = (VDD_MAX – VOUT) * IOUT, since VOUT – IOUT * RL = (VDD_MAX – IOUT * RL) * IOUT = (3.6V – 17mA * 50Ω) * 17mA Total Power Dissipation per output pair = 46.8mW ICS831721AGI REVISION A AUGUST 19, 2011 14 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Package Outline and Package Dimensions Table 7. θJA vs. Air Flow Table for a 16 Lead TSSOP θJA vs. Air Flow Meters per Second Multi-Layer PCB, JEDEC Standard Test Boards 0 1 2.5 100.3°C/W 96.0°C/W 93.9°C/W Transistor Count The transistor count for ICS831721I is: 632 Package Outline and Package Dimensions Package Outline - G Suffix for 16 Lead TSSOP All Dimensions in Millimeters Symbol Minimum Maximum E 6.40 Basic E1 4.30 4.50 e 0.65 Basic L 0.45 0.75 α 0° 8° aaa 0.10 Reference Document: JEDEC Publication 95, MO-153 Table 8. Package Dimensions for 16 Lead TSSOP All Dimensions in Millimeters Symbol Minimum Maximum N 16 A 1.20 A1 0.05 0.15 A2 0.80 1.05 b 0.19 0.30 c 0.09 0.20 D 4.90 5.10 ICS831721AGI REVISION A AUGUST 19, 2011 15 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER Ordering Information Table 9. Ordering Information Part/Order Number 831721AGILF 831721AGILFT Marking 31721AIL 31721AIL Package Lead-Free, 16 Lead TSSOP Lead-Free, 16 Lead TSSOP Shipping Packaging Tube 2500 Tape & Reel Temperature -40°C to 85°C -40°C to 85°C NOTE: Parts that are ordered with an “LF” suffix to the part number are the Pb-Free configuration and are RoHS compliant While the information presented herein has been checked for both accuracy and reliability, Integrated Device Technology (IDT) assumes no responsibility for either its use or for the infringement of any patents or other rights of third parties, which would result from its use. No other circuits, patents, or licenses are implied. This product is intended for use in normal commercial and industrial applications. Any other applications, such as those requiring high reliability or other extraordinary environmental requirements are not recommended without additional processing by IDT. IDT reserves the right to change any circuitry or specifications without notice. IDT does not authorize or warrant any IDT product for use in life support devices or critical medical instruments. ICS831721AGI REVISION A AUGUST 19, 2011 16 ©2011 Integrated Device Technology, Inc. ICS831721I Data Sheet DIFFERENTIAL CLOCK/DATA MULTIPLEXER We’ve Got Your Timing Solution 6024 Silver Creek Valley Road San Jose, California 95138 Sales 800-345-7015 (inside USA) +408-284-8200 (outside USA) Fax: 408-284-2775 www.IDT.com/go/contactIDT Technical Support [email protected] +480-763-2056 DISCLAIMER Integrated Device Technology, Inc. (IDT) and its subsidiaries reserve the right to modify the products and/or specifications described herein at any time and at IDT’s sole discretion. All information in this document, including descriptions of product features and performance, is subject to change without notice. Performance specifications and the operating parameters of the described products are determined in the independent state and are not guaranteed to perform the same way when installed in customer products. The information contained herein is provided without representation or warranty of any kind, whether express or implied, including, but not limited to, the suitability of IDT’s products for any particular purpose, an implied warranty of merchantability, or non-infringement of the intellectual property rights of others. This document is presented only as a guide and does not convey any license under intellectual property rights of IDT or any third parties. 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