Application Report SNOA569A – November 2011 – Revised April 2013 AN-2195 Driving High Speed ADCs with the LMH6521 DVGA for High IF AC-Coupled Applications ..................................................................................................................................................... ABSTRACT This application report discusses driving high speed ADCs with the Texas Instruments LMH6521 DVGA for high IF AC-coupled applications. 1 2 3 4 5 6 Contents Introduction .................................................................................................................. Circuit Description ........................................................................................................... Tapped Inductor Band-pass Filter ........................................................................................ IF-Sampling Frequency Plan .............................................................................................. System Performance ....................................................................................................... Optimal Performance ....................................................................................................... 2 2 2 4 4 5 List of Figures ..... .................................................................. 192 MHz Tapped-L Filter Profile .......................................................................................... Using Impedance Transform to Realize Voltage Gain ................................................................. SFDR Performance vs. Input Signal Frequency ........................................................................ SNR Performance vs. Input Signal Frequency.......................................................................... Output Inductors at 90 Degrees........................................................................................... 1 Tapped-L Band-pass Filter For fc = 192 MHz with a 20 MHz Bandwidth Designed for 100Ω Impedance 2 2 Single-Ended Tapped-L Band-pass Filter Segments 3 3 4 5 6 7 3 4 4 4 5 List of Tables 1 SNR and SFDR Results ................................................................................................... 5 All trademarks are the property of their respective owners. SNOA569A – November 2011 – Revised April 2013 Submit Documentation Feedback AN-2195 Driving High Speed ADCs With the LMH6521 DVGA for High IF AC-Coupled Applications Copyright © 2011–2013, Texas Instruments Incorporated 1 Introduction 1 www.ti.com Introduction Sampled data systems can be categorized into two main types. The first and simplest is the baseband system known as the “1st Nyquist-zone” system. The second is a more complex under-sampled system, often referred to as the sub-sampled system or Intermediate frequency (IF)-sampled system. Baseband system applications are generally DC-coupled while the IF-sample systems applications tend to be ACcoupled. In this application reoprt, the LMH6521 is combined with Texas Instruments high-speed analogto-digital convertor (ADC), the ADC16DV160, that is optimized for an IF frequency of 192 MHz. The LMH6521 contains two high-performance, digitally controlled variable-gain amplifiers (DVGA) with exceptional gain and phase matching between channels over the entire attenuation range that mates nicely with the dual channels of the ADC16DV160. The ADC16DV160 is a monolithic, dual-channel, highperformance CMOS ADC capable of converting analog input signals into 16-bit digital words at rates up to 160 MSPS. The output noise density of the LMH6521 is typically 33 nV/Hz, which makes the LMH6521 suitable to drive 14-bit to 16-bit ADC’s. 2 Circuit Description As shown in Figure 1, a low loss 1:4 (impedance ratio) input transformer TC4-1W is used to match the LMH6521’s 200Ω balanced input impedance to a 50Ω unbalanced signal source resulting in a low input insertion loss of 0.8 dB. The LMH6521 provides variable gain, isolation, and source matching to the ADC16DV160. The band-pass filter between the LMH6521 and ADC16DV160 provides attenuation of the amplifier distortion products and noise outside the Nyquist zone helping to preserve the available SNR of the ADC. The filter is a 3rd order 200Ω matched tapped-L anti-aliasing filter designed for an intermediate frequency of 192 MHz and a 20 MHz bandwidth. 1 PH 0.01 PF TC4-1W 1:4 40.2: 0.01 PF 0.01 PF L4 180 nH 4 pF 50: ½ LMH6521 50: L3 160nH C4 4 pF L5 15 nH C5 41 pF ADC16DV160 50: 0.01 PF 1 PH 40.2: 0.01 PF L3 160 nH L4 180 nH VRM 4 pF Figure 1. Tapped-L Band-pass Filter For fc = 192 MHz with a 20 MHz Bandwidth Designed for 100Ω Impedance 3 Tapped Inductor Band-pass Filter The anti-aliasing band-pass filter is called a “Tapped-L” or “Tapped Inductor” filter because it uses series inductors for the T-match impedance transform. Figure 2 shows L1, L2, and the combination of C11 and C12 to make up the T-match structure of the filter. As shown in Figure 2, the filter is broken up into three segments for analysis purposes: down impedance transform, up impedance transform, and band-pass tank. The tank provides a 1st-order band-pass profile while the impedance transform matches the load resistance, RL, to the source resistance, RS, at the designated center frequency and increases high frequency roll-off to 4th order. 2 AN-2195 Driving High Speed ADCs With the LMH6521 DVGA for High IF AC-Coupled Applications SNOA569A – November 2011 – Revised April 2013 Submit Documentation Feedback Copyright © 2011–2013, Texas Instruments Incorporated Tapped Inductor Band-pass Filter www.ti.com Down Impedance Transform Up Impedance Transform Bandpass Tank RS L1 L2 C11 C12 CT LT RL Figure 2. Single-Ended Tapped-L Band-pass Filter Segments Frequencies above the high frequency corner of 202 MHz have greater than 4th-order roll-off (>24dB/octave) whereas lower frequencies below 182 MHz will have only a 1st order roll-off. At lower frequencies there is less total bandwidth for aliasing. This filter scheme can provide > 40 dB harmonic attenuation with minimal filter complexity and nearly 0 dB insertion loss to allow the LMH6521 to drive the ADC input to full scale without compressing at the supply rails. Ripple in the pass-band is easily kept below 1 dB. The equivalent noise bandwidth (ENBW) of this filter is approximately 44 MHz. Figure 3 shows the filter profile over frequency. 0 GAIN (db) -4 -8 -12 -16 -20 -24 120 140 160 180 200 220 240 260 280 FREQUENCY (MHz) Figure 3. 192 MHz Tapped-L Filter Profile Inductor L5 (Figure 1) in parallel with the ADC input capacitance and C5 to form a resonant tank to help ensure the ADC input looks like a real resistance at the target IF center frequencies. Inductor L5 shorts the ADC inputs at dc which introduces a zero into the transfer function. The value of C5 should be adjusted with respect to the ADC input capacitance. Since C5 is parallel to CIN(ADC), the equivalent value for C5 is equal to the calculated value (C5calculated) minus the ADC input capacitance, CIN(ADC). SNOA569A – November 2011 – Revised April 2013 Submit Documentation Feedback AN-2195 Driving High Speed ADCs With the LMH6521 DVGA for High IF AC-Coupled Applications Copyright © 2011–2013, Texas Instruments Incorporated 3 IF-Sampling Frequency Plan 4 www.ti.com IF-Sampling Frequency Plan The ADC16DV160 sub-samples the 192 MHz IF signal with a 153.6 MSPS clock so that the 20MHz signal band aliases to the center of the first Nyquist zone at 38.4 MHz. A large benefit of this plan is the placement of the 2nd order harmonic, H2, completely out of the band of interest when it aliases. HD3 cannot be excluded from the signal band and must be reduced in the system as much as possible. The frequency ranges of the HD2 and HD3 aliases are shown in Figure 4. IF Band IF Band HD2 HD3 [MHz] 38.4 76.8 Figure 4. Using Impedance Transform to Realize Voltage Gain 5 System Performance Figure 5 and Figure 6 show the SFDR and SNR performance over frequency of the circuit shown in Figure 1. The input signal is measured at −1, −3, and −6 dBFS of the ADC. 80 PO = -1dBFS PO = -3dBFS PO = -6dBFS MAGNITUDE (dBFS) MAGNITUDE (dBFS) 95 90 85 80 75 182 75 70 65 187 192 197 FREQUENCY (MHz) 202 Figure 5. SFDR Performance vs. Input Signal Frequency 4 PO = -1dBFS PO = -3dBFS PO = -6dBFS 182 187 192 197 FREQUENCY (MHz) 202 Figure 6. SNR Performance vs. Input Signal Frequency AN-2195 Driving High Speed ADCs With the LMH6521 DVGA for High IF AC-Coupled Applications SNOA569A – November 2011 – Revised April 2013 Submit Documentation Feedback Copyright © 2011–2013, Texas Instruments Incorporated Optimal Performance www.ti.com With a 2-tone large input signal with the LMH6521 set to maximum gain (26dB) to drive an input signal level at the ADC of −1 dBFS, the SNR and SFDR results are shown in Table 1 compared to the stand alone ADC16DV160 specifications. Table 1. SNR and SFDR Results Configuration 6 ADC Input SNR (dBFS) SFDR (dBFS) LMH6521 + BPF + ADC16DV160 −1 dBFS 75.5 82 ADC16DV160 only −1 dBFS 76 89 Optimal Performance Placement of the LMH6521 relative to the ADC16DV160 is essential for optimal performance. It is recommended that the amplifier be placed as close the ADC as possible and with excellent layout and decoupling techniques to achieve the desired system performance. One way to improve channel isolation is to place the output inductors of each channel of the LMH6521 90 degrees to reduce magnetic coupling as shown in Figure 7. As a minimum, a 4-layer board should be utilized with one ground, one power, and two signal layers. However, by adding more layers, thicker top and bottom metal layers, and additional through vias will improve heat dissipation of the LMH6521 and improve performance. The LMH6521 DVGA is well suited to drive Texas Instruments family of high speed MSPS data converters: ADC10DV200, ADC12EU050, ADC12C170, ADC16V130, and ADC16DV160. Contact a Texas Instruments representative to obtain documentation on the SP16160CH2RB reference design files. Figure 7. Output Inductors at 90 Degrees SNOA569A – November 2011 – Revised April 2013 Submit Documentation Feedback AN-2195 Driving High Speed ADCs With the LMH6521 DVGA for High IF AC-Coupled Applications Copyright © 2011–2013, Texas Instruments Incorporated 5 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. All semiconductor products (also referred to herein as “components”) are sold subject to TI’s terms and conditions of sale supplied at the time of order acknowledgment. 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