CM1236 ESD Clamp Array for High Speed Data Line Protection Product Description The CM1236 is ideal for protecting systems with high data and clock rates or for circuits requiring low capacitive loading and tightly controlled signal skews (with channel−to−channel matching at 2% max deviation). The device is particularly well−suited for protecting systems using high−speed ports such as DisplayPort or HDMI, along with corresponding ports in removable storage, digital camcorders, DVD−RW drives and other applications where extremely low loading capacitance with ESD protection are required. The CM1236 also features easily routed “pass−through” pinouts in a RoHS compliant (lead−free), 16−lead WDFN, small footprint package. 16 1 WDFN16 DE SUFFIX CASE 511AY PINOUT DIAGRAM Features • ESD Protection for 4 Pairs of Differential Channels • ESD Protection to: • • • • • • http://onsemi.com • IEC61000−4−2 Level 4 (ESD) at ±8 kV Contact Discharge • IEC61000−4−4 (EFT) 40 A (5/50 ns) • IEC61000−4−5 (Lighting) 3.5 A (8/20 ms) Pass−through Impedance Matched Clamp Architecture Flow−through Routing for High−speed Signal Integrity Minimal Line Capacitance Change with Temperature and Voltage 100 W Matched Impedance for Each Paired Differential Channel Each I/O Pin can Withstand Over 1000 ESD Strikes* RoHS Compliant (lead−free) WDFN−16 Package Applications Out_1+ Out_1− Out_2+ Out_2− Out_3+ Out_3− Out_4+ Out_4− 1 GND In_1+ In_1− In_2+ In_2− In_3+ In_3− In_4+ In_4− (Bottom View) ORDERING INFORMATION See detailed ordering and shipping information in the package dimensions section on page 8 of this data sheet. • DVI, DisplayPort, and HDMI Ports in Notebooks, Set Top Boxes, Digital TVs, and LCD Displays • General Purpose High−speed Data Line ESD Protection *Standard test condition is IEC61000−4−2 level 4 test circuit with each pin subjected to ±8 kv contact discharge for 1000 pulses. Discharges are timed at 1 second intervals and all 1000 strikes are completed in one continuous test run. The part is then subjected to standard production test to verify that all of the tested parameters are within spec after the 1000 strikes. © Semiconductor Components Industries, LLC, 2014 January, 2014 − Rev. 5 1 Publication Order Number: CM1236/D CM1236 Figure 1. Block Diagram ESD Protection Architecture characteristic impedance that helps optimize 100 W load impedance applications such as the HDMI high speed data lines. NOTE: When each of the channels are used individually for single−ended signal lines protection, the individual channel provides 50 W characteristic impedance matching. The load impedance matching feature of the CM1236 helps to simplify system designer’s PCB layout considerations in impedance matching and also eliminates associated passive components. The route through the architecture enables the CM1236 to provide matched impedance for the signal path between the connector and the ASIC. Besides this function, this circuit arrangement also changes the way the parasitic inductance interacts with the ESD protection circuit and helps reduce the IRESIDUAL current to the ASIC. Conceptually, an ESD protection device performs the following actions upon an ESD strike discharge into a protected ASIC (see Figure 2): 1. When an ESD potential is applied to the system under test (contact or air−discharge), Kirchoff’s Current Law (KCL) dictates that the Electrical Overstress (EOS) currents will immediately divide throughout the circuit, based on the dynamic impedance of each path. 2. Ideally, the classic shunt ESD clamp will switch within 1 ns to a low−impedance path and return the majority of the EOS current to the chassis shield/reference ground. In actuality, if the ESD component’s response time (tCLAMP) is slower than the ASIC it is protecting, or if the Dynamic Clamping Resistance (RDYN) is not significantly lower than the ASIC’s I/O cell circuitry, then the ASIC will have to absorb a large amount of the EOS energy, and be more likely to fail. 3. Subsequent to the ESD/EOS event, both devices must immediately return to their original specifications, and be ready for an additional strike. Any deterioration in parasitics or clamping capability should be considered a failure, since it can then affect signal integrity or subsequent protection capability. (This is known as “multi−strike” capability.) In the CM1236 architecture, the signal line leading the connector to the ASIC routes through the CM1236 chip which provides 100 W matched differential channel Figure 2. Standard ESD Protection Device Block Diagram http://onsemi.com 2 CM1236 The Architecture Advantages leading to the ESD protection element. This limits the speed that the ESD pulse can discharge through the ESD protection element. In the architecture, the inductive elements are in series to the conduction path leading to the protected device. The elements actually help to limit the current and voltage striking the protected device. First the reactance of the inductive element, L1, on the connector side when an ESD strike occurs, acts in the opposite direction of the ESD striking current. This helps limit the peak striking voltage. Then the reactance of the inductive element, L2, on the ASIC side forces this limited ESD strike current to be shunted through the ESD protection diodes. At the same time, the voltage drop across both series element acts to lower the clamping voltage at the protected device terminal. Through this arrangement, the inductive elements also tune the impedance of the ESD protection element by cancelling the capacitive load presented by the ESD diodes to the signal line. This improves the signal integrity and makes the overall ESD protection device more transparent to the high bandwidth data signals passing through the channel. The innovative architecture turns the disadvantages of the parasitic inductive elements into useful components that help to limit the ESD current strike to the protected device and also improves the signal integrity of the system by balancing the capacitive loading effects of the ESD diodes. At the same time, this architecture provides an impedance matched signal path for 50 W loading applications. Board designs can take advantage of precision internal component matching for improved signal integrity, which is not otherwise possible with discrete components at the system level. This helps to simplify the PCB layout considerations by the system designer and eliminates the associated passive components for load matching that is normally required with standard ESD protection circuits. Each ESD channel consists of a pair of diodes in series which steer the positive or negative ESD current pulse to either the Zener diode or to ground. This embedded Zener diode also serves to eliminate the need for a separate bypass capacitor to absorb positive ESD strikes to ground. The CM1236 protects against ESD pulses up to ±8 kv contact per the IEC 61000−4−2 standard. Figure 3 illustrates a standard ESD protection device. The inductor element represents the parasitic inductance arising from the bond wire and the PCB trace leading to the ESD protection diodes. Figure 3. Standard ESD Protection Model Figure 4 illustrates a standard ESD protection device. The inductor element represents the parasitic inductance arising from the bond wire and the PCB trace leading to the ESD protection diodes. Figure 4. CM1234 ESD Protection Model CM1236 Inductor Elements In the CM1236 architecture, the inductor elements and ESD protection diodes interact differently compared to the standard ESD model. In the standard ESD protection device model, the inductive element presents high impedance against high slew rate strike voltage, i.e. during an ESD strike. The impedance increases the resistance of the conduction path http://onsemi.com 3 CM1236 PIN DESCRIPTIONS Pin Name Description 1 In_1+ Bidirectional Clamp to ASIC (inside system) 2 In_1− Bidirectional Clamp to ASIC (inside system) 3 In_2+ Bidirectional Clamp to ASIC (inside system) 4 In_2− Bidirectional Clamp to ASIC (inside system) 5 In_3+ Bidirectional Clamp to ASIC (inside system) 6 In_3− Bidirectional Clamp to ASIC (inside system) 7 In_4+ Bidirectional Clamp to ASIC (inside system) 8 In_4− Bidirectional Clamp to ASIC (inside system) 9 Out_4− Bidirectional Clamp to Connector (outside system) 10 Out_4+ Bidirectional Clamp to Connector (outside system) 11 Out_3− Bidirectional Clamp to Connector (outside system) 12 Out_3+ Bidirectional Clamp to Connector (outside system) 13 Out_2− Bidirectional Clamp to Connector (outside system) 14 Out_2+ Bidirectional Clamp to Connector (outside system) 15 Out_1− Bidirectional Clamp to Connector (outside system) 16 Out_1+ Bidirectional Clamp to Connector (outside system) PAD GND Ground return to shield http://onsemi.com 4 CM1236 Specifications Table 1. ABSOLUTE MAXIMUM RATINGS Parameter Rating Units Operating Temperature Range −40 to +85 °C Storage Temperature Range −65 to +150 °C Breakdown Voltage (Positive) 6 V Stresses exceeding those listed in the Maximum Ratings table may damage the device. If any of these limits are exceeded, device functionality should not be assumed, damage may occur and reliability may be affected. Table 2. ELECTRICAL OPERATING CHARACTERISTICS (All parameters specified at TA = –40°C to +85°C unless otherwise noted.) Symbol Parameter VIN I/O Voltage Relative to GND IIN Continuous Current through signal pins (IN to OUT) 1000 Hr IF Conditions TA = 25°C; VN = 0 V, VTEST = 5 V ESD Protection − Peak Discharge Voltage at any channel input, in system: Contact discharge per IEC 61000−4−2 Standard TA = 25°C IRES Residual ESD Peak Current on RDUP (Resistance of Device Under Protection) IEC 61000−4−2 8 kV; RDUP = 5 W, TA = 25°C VCL Channel Clamp Voltage (Channel clamp voltage per IEC 61000−4−5 Standard) Positive Transients Negative Transients IPP = 1 A, TA = 25°C, tP = 8/20 mS Dynamic Resistance Positive Transients Negative Transients IPP = 1 A, TA = 25°C, tP = 8/20 mS; Differential Impedance TDR excursion from 100 W characteristic impedance transmission line; TR = 200 ps; (Notes 1 and 2) Differential Channels pair characteristic impedance TR = 200 ps; (Notes 1 and 2) Channel−to−Channel Impedance Match (Differential) TR = 200 ps; TA = 25°C; (Notes 1 and 2) Zo DZo Max 5.5 100 Channel Leakage Current ZTDR Typ −0.5 VESD RDYN Min ±0.1 Units V mA ±1.0 mA kV ±8 3.0 A V +9.2 −1.6 W 0.6 0.5 97 107 W 100 W 2 % 1. This parameter is guaranteed by design and verified by device characterization. 2. Impedance values for deviation from continuous 100 W uncompensated differential microstrip, with typical layout as measured via TDR with 200 ps effective incident risetime. See Figure 7. Product parametric performance is indicated in the Electrical Characteristics for the listed test conditions, unless otherwise noted. Product performance may not be indicated by the Electrical Characteristics if operated under different conditions. http://onsemi.com 5 CM1236 Performance Information Graphical Comparison and Test Setup Figure 5 shows that the CM1236 (ESD protector) lowers the peak voltage and clamping voltage by 45% across a wide range of loading conditions in comparison to a standard ESD protection device. Figure 6 also indicates that the DUP/ASIC protected by the CM1236 dissipates less energy than a standard ESD protection device. This data was derived using the test setups shown in Figure 7. Vpeak VCLAMP(peak) (Normalized) STD ESD Device 1.0 0.8 0.6 CM1236 0.4 0.2 0 5 10 Residual Current (Peak) 0.5 RESIDUAL CURRENT (Normalized) 1.2 0.3 CM1236 0.2 0.1 0 20 STD ESD Device 0.4 5 10 20 RDUP (W) RDUP (W) Figure 5. VCLAMP vs. RDUP* (ASIC) – 8 kV Contract Strike Figure 6. IRESIDUAL vs. RDUP* (ASIC) – 8 kV Contract Strike *RDUP is the emulated Dynamic Resistance (load) of the Device Under Protection (DUP). See Figure 7. IEC 61000−4−2 Test Standards IEC 61000−4−2 Test Standards Voltage Probe Voltage Probe CM1236 Standard ESD Device Standard ESD Device Test Setup Current Probe Device Under Protection (DUP) Device Under Protection (DUP) RVARIABLE RVARIABLE IRESIDUAL CM1236 Test Setup Figure 7. Test Setups: Standard Device (Left) and CM1236 (Right) http://onsemi.com 6 Current Probe IRESIDUAL CM1236 100.0 W Figure 8. Typical Channel TDR Measured Across Out_x and In_x Per Each Differential Channels Pair (Typical 200 ps Incident Rise Time) Application Information CM1236 Application and Guidelines As a general rule, the CM1236 ESD protection array should be located as close as possible to the point of entry of expected electrostatic discharges with minimum PCB trace lengths to the ground planes and between the signal input and the ESD device to minimize stray series inductance. Figure 9. Application of Positive ESD Pulse Between Input Channel and Ground Additional Information See also ON Semiconductor Application Note “Design Considerations for ESD Protection,” in the Applications section at www.onsemi.com. Figure 10. Typical PCB Layout http://onsemi.com 7 CM1236 Ordering Information PART NUMBERING INFORMATION NOTE: Pin Package Ordering Part Number (Lead−Free Finish) Part Marking 16 WDFN−16 CM1236−08DE CM1236−08 Parts are shipped in Tape & Reel form unless otherwise specified. TAPE AND REEL SPECIFICATIONS † Part Number Package Size (mm) Pocket Size (mm) B0 X A0 X K0 Tape Width W Reel Diameter Qty per Reel P0 P1 CM1236 6.00 X 4.00 X 0.75 6.30 X 4.30 X 1.10 12 mm 330 mm (13″) 3000 4 mm 8 mm †For information on tape and reel specifications, including part orientation and tape sizes, please refer to our Tape and Reel Packaging Specifications Brochure, BRD8011/D. http://onsemi.com 8 CM1236 PACKAGE DIMENSIONS WDFN16, 6x4, 0.75P CASE 511AY−01 ISSUE O A B D PIN ONE REFERENCE 2X 0.10 C ÉÉ ÉÉ ÉÉ 0.10 C 2X L L1 DETAIL A E ALTERNATE TERMINAL CONSTRUCTIONS TOP VIEW ÉÉÉ ÇÇÇ ÇÇÇ EXPOSED Cu (A3) DETAIL B 0.10 C A A1 SIDE VIEW DETAIL A D2 1 C 16X MOLD CMPD SEATING PLANE 16 e e/2 A3 ALTERNATE CONSTRUCTIONS MILLIMETERS MIN MAX 0.70 0.80 0.00 0.05 0.20 REF 0.20 0.30 6.00 BSC 5.05 5.15 4.00 BSC 1.75 1.85 0.75 BSC 0.70 REF 0.35 0.45 −−− 0.15 L 8 RECOMMENDED SOLDERING FOOTPRINT* E2 K ÇÇ ÉÉ DIM A A1 A3 b D D2 E E2 e K L L1 A1 DETAIL B 0.08 C NOTE 4 NOTES: 1. DIMENSIONING AND TOLERANCING PER ASME Y14.5M, 1994. 2. CONTROLLING DIMENSION: MILLIMETERS. 3. DIMENSION b APPLIES TO PLATED TERMINAL AND IS MEASURED BETWEEN 0.15 AND 0.30 MM FROM TERMINAL TIP. 4. COPLANARITY APPLIES TO THE EXPOSED PAD AS WELL AS THE TERMINALS. L 9 5.26 16X b 0.10 C A B 0.05 C 16X 0.63 NOTE 3 BOTTOM VIEW 1.96 16X 0.32 4.30 0.75 PITCH DIMENSION: MILLIMETERS *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC owns the rights to a number of patents, trademarks, copyrights, trade secrets, and other intellectual property. A listing of SCILLC’s product/patent coverage may be accessed at www.onsemi.com/site/pdf/Patent−Marking.pdf. SCILLC reserves the right to make changes without further notice to any products herein. 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