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| CDB35L00-X4 2.7 W x 4 CS35L00 Amplifier Demonstration Board Features Contains 4 CS35L00 Hybrid Class-D Amplifiers Selectable +6 dB or +12 dB Gain Selectable Operational Modes Device Shutdown Control Delivers 2.7 W/Ch into 4 at 10 % THD+N Delivers 1.6 W/Ch into 8 at 10 % THD+N Differential Mono Analog Inputs for each Description The CDB35L00-X4 demonstrates the CS35L00 high-efficiency Hybrid Class-D audio amplifier. This demonstration board implements a four-channel, quad amplifier system that delivers 2.7 W per full-bridge channel into 4- loads using a single +5 V supply. Differential audio inputs can easily be connected through the J10, J20, J30, and J40 headers. If desired, the gain can be adjusted through the optional input resistors. Component landings are available for an optional EMI output filter. The CDB35L00-X4 can be configured to evaluate the four operational modes and two gain settings of the CS35L00 amplifier. Mode, Gain, and Shutdown control is available through the S1 switch. Hybrid control is available through the R13, R23, R33, and R43 resistors. ORDERING INFORMATION CDB35L00 CS35L00-X4 Demo Board CS35L00 Amplifier Demonstrates Recommended 4-Layer Layout and Grounding Arrangements - Optional Output Filter Connections - Optional Gain Adjustment Resistors Powered by Single +2.5-5.5 V Power Supply Control Switch (S1) VBATT Power (J1) Analog Input (J10) Optional Gain Adjustment CS35L00 (U1) Optional Output Filter Speaker Output (J11) 4 or 8 Analog Input (J20) Optional Gain Adjustment CS35L00 (U2) Optional Output Filter Speaker Output (J21) 4 or 8 Analog Input (J30) Optional Gain Adjustment CS35L00 (U3) Optional Output Filter Speaker Output (J31) 4 or 8 Analog Input (J40) Optional Gain Adjustment CS35L00 (U4) Optional Output Filter Speaker Output (J41) 4 or 8 http://www.cirrus.com Copyright Cirrus Logic, Inc. 2010 (All Rights Reserved) APR '10 DS913DB2 CDB35L00-X4 TABLE OF CONTENTS 1. SYSTEM OVERVIEW ............................................................................................................................. 3 1.1 CS35L00 Hybrid Class-D Amplifier .................................................................................................. 3 1.2 Power Supply ................................................................................................................................... 3 1.3 Operational Modes ........................................................................................................................... 3 1.3.1 Operational Mode Control ....................................................................................................... 3 1.4 Shutdown Control ............................................................................................................................ 4 1.4.1 Shutdown Control Resistors .................................................................................................... 5 1.5 Gain Control ..................................................................................................................................... 5 1.5.1 Optional Gain Adjustment Resistors ....................................................................................... 5 1.6 Differential Analog Inputs ................................................................................................................. 6 1.7 Speaker Outputs .............................................................................................................................. 6 1.7.1 Optional Speaker Output EMI Filter Components ................................................................... 6 2. GROUNDING AND POWER SUPPLY DECOUPLING .......................................................................... 7 2.1 Power Supply Decoupling ................................................................................................................ 7 2.2 Electromagnetic Interference (EMI) ................................................................................................. 7 2.2.1 Suppression of EMI at the Source ........................................................................................... 7 3. SYSTEM CONNECTORS AND JUMPERS ............................................................................................ 8 4. CDB SCHEMATIC .................................................................................................................................. 9 4.1 Bill of Materials ............................................................................................................................... 10 5. CDB LAYOUT ....................................................................................................................................... 11 6. REVISION HISTORY ............................................................................................................................ 12 LIST OF FIGURES Figure 1.Hybrid Control Resistors ............................................................................................................... 4 Figure 2.Shutdown Control Resistors ......................................................................................................... 5 Figure 3.Optional Bypass Trace Cut Locations for U1 ................................................................................ 6 Figure 4.CDB35L00-X4 Schematic ............................................................................................................. 9 Figure 5.CDB35L00-X4 Top Side Component Placement ........................................................................ 11 Figure 6.CDB35L00-X4 Bottom Side Component Placement ................................................................... 11 Figure 7.CDB35L00-X4 Layer 1 Copper ................................................................................................... 11 Figure 8.CDB35L00-X4 Layer 2 Copper ................................................................................................... 11 Figure 9.CDB35L00-X4 Layer 3 Copper ................................................................................................... 11 Figure 10.CDB35L00-X4 Layer 4 Copper ................................................................................................. 11 LIST OF TABLES Table 1. S1 Switch GAIN & MODE Configurations ..................................................................................... 3 Table 2. Hybrid Control Resistor & S1 Switch MODE Configurations ......................................................... 4 Table 3. S1 Switch Default Shutdown Configurations ................................................................................. 5 Table 4. System Input and Output Connections ......................................................................................... 8 Table 5. S1 Switch Settings ........................................................................................................................ 8 Table 6. Bill of Materials Listing ................................................................................................................ 10 2 DS913DB2 CDB35L00-X4 1. SYSTEM OVERVIEW The CDB35L00-X4 demonstration board is an practical means for evaluating the CS35L00 2.7 W Hybrid Class-D amplifier with low idle current consumption. A differential mono analog input signal interface is provided for each device. Optional input gain and output filtering component placeholders are provided for easy modification to custom tune the CS35L00 for the user's specific system requirements. 1.1 CS35L00 Hybrid Class-D Amplifier The CS35L00 Hybrid Class-D amplifier is a 2.7 W mono, full-bridge, closed-loop, audio amplifier available in a 10-pin, 3 mm x 3 mm, DFN package. A complete description of the CS35L00 is included in the CS35L00 product data sheet. 1.2 Power Supply A single +2.5 to +5.5 VDC power supply is required to power the CDB35L00-X4. The supply must be capable of delivering sufficient current for the intended power output. The supply provides power to each of the four CS35L00 amplifiers. The power supply connection to the board is provided by the header J1. The positive terminal is labeled VBATT. The ground terminal is labeled GND. 1.3 Operational Modes The CS35L00 device has 4 different operational modes. Each of the 4 operational modes requires different board configuration as described in Section 1.3.1 and Section 1.3.1.1. The operational modes of the CS35L00 are listed below. More information on the specifics of each operational mode can be found in the CS35L00 product datasheet. * * * * SD: Standard Class-D Mode FSD: Reduced Frequency Standard Class-D Mode HD: Hybrid Class-D Mode FHD: Reduced Frequency Hybrid Class-D Mode The CDB35L00-X4 demonstration board schematic is shown in Figure 4 on page 9. 1.3.1 Operational Mode Control Using a combination of the S1 switch and the hybrid control resistors, as described in Section 1.3.1.1, allows the CDB35L00-X4 to be configured in all 4 of the operational modes listed in Section 1.3. Each CS35L00's MODE pin on the CDB35L00-X4 board is connected to the S1 switch labeled MODE as shown in Figure 4 on page 9. The MODE pin controls whether all four of the CS35L00 devices on the CDB35L00-X4 board are operating in one of the reduced frequency modes (FSD or FHD) or in one of the higher frequency modes (SD or HD). GAIN LOW HIGH +12 dB +6 dB MODE FSD / FHD SD / HD Table 1. S1 Switch GAIN & MODE Configurations Table 1 on page 3 and Table 3 on page 5 show the S1 switch-controlled configuration options on the CDB35L00-X4 board. More configuration options are available by removing or repopulating 0 resistors as described in Section 1.4. Note: In order to avoid transient audio signals, the CS35L00 devices should be shutdown either via the S1 switch or by removing power when the operational mode is being changed. DS913DB2 3 CDB35L00-X4 1.3.1.1 Hybrid Control Resistor Configuration Each CS35L00 device has a hybrid control resistor. When the hybrid control resistor for each CS35L00 is populated, it connects the LFILT+ pin to VBATT and enables the Standard Class-D functionality (SD or FSD modes) for the corresponding device. When the hybrid control resistor for each CS35L00 is not populated, LFILT+ is floating, and the Hybrid Class-D functionality (HD or FHD modes) is enabled. The hybrid control resistors (R13, R23, R33, R43) are located on the bottom side of the board adjacent to the LFILT+ decoupling capacitor and are highlighted in blue in Figure 1. A combination of the hybrid control resistors and the S1 MODE switch allow the CS35L00 devices (U1-U4) on the CDB35L00-X4 board to be configured in all 4 of the operational modes. There is no requirement to have the all four of the CS35L00 devices configured in the same mode. Each device can be configured to the user's requirements. Table 2 lists the configuration options available using the hybrid control resistors and the S1 MODE switch. Figure 1. Hybrid Control Resistors S1 MODE Switch: GND Hybrid Control Resistor R13: VBATT R13: Removed R23: VBATT R23: Removed R33: VBATT R33: Removed R43: VBATT R43: Removed U1 = FSD U1 = FHD U2 = FSD U2 = FHD U3 = FSD U3 = FHD U4 = FSD U4 = FHD VBATT U1 = SD U1 = HD U2 = SD U2 = HD U3 = SD U3 = HD U4 = SD U4 = HD Table 2. Hybrid Control Resistor & S1 Switch MODE Configurations 1.4 Shutdown Control The S1 switch implements shutdown control for the four CS35L00 devices on the CDB35L00-X4. SD1-2 controls the shutdown for U1 and U2. SD3-4 controls the shutdown for U3 and U4 as shown in Table 3 and on the schematic in Figure 4 on page 9. 4 DS913DB2 CDB35L00-X4 1.4.1 Shutdown Control Resistors The CDB35L00-X4 contains 0 ohm resistors (R1-R4) which allow the individual CS35L00 shutdown pins to be disconnected from the S1 switch or connected to an external control device. These resistors are located on the back side of the CDB35L00-X4 board near S1, as shown highlighted in blue in Figure 2. R1-R4 are connected to SD on U1-U4, respectively. It is recommended that the individual shutdown line pull-up resistors for U1-U4 (R10, R20, R30, R40) be left populated to help prevent the individual SD control lines from floating. Figure 2. Shutdown Control Resistors SD1-2 LOW HIGH U1 & U2 OFF U1 & U2 ON SD3-4 U3 & U4 OFF U3 & U4 ON Table 3. S1 Switch Default Shutdown Configurations 1.5 Gain Control The amplifier gain of the CS35L00 can be configured to operate with either a +6 dB gain or a +12 dB gain as shown in Table 1 on page 3. The amplifier gain is selectable through the GAIN setting on the S1 switch. This is connected to the GAIN_SEL pins on the four CS35L00 devices as shown in Figure 4 on page 9. Note: The CS35L00 devices should be placed into shutdown via either the S1 switch or by removing power before changing the GAIN setting. 1.5.1 Optional Gain Adjustment Resistors The CDB35L00-X4 contains optional gain adjustment resistor placeholders for each CS35L00 device (R11, R12, R21, R22, R31, R32, R41, R42). By default these are not populated and the CS35L00 operates at its gain control setting as set by the S1 switch. See Table 1. The gain adjustment resistors are only necessary when a gain of +6 dB or a gain of +12 dB is not desired. By adding series resistance to the input, the signal amplitude to the CS35L00 will be reduced, and will reduce the overall system gain. The typical input impedance values of the CS35L00 as well as how to calculate the resistor values for a desired gain can be found in the device datasheet. In order to use the optional gain adjustment resistors for U1, the traces between the R11 pads and the traces between the R12 pads must be cut in order to break the bypass circuit before populating R11 and R12 with the desired resistance values. The location of these required cuts are shown in Figure 3 on page 6. After the trace between the pads has been broken, the gain adjustment resistors can be added to the board. The gain adjustment resistors for U2, U3, and U4 can be added in the same manner as is described for U1 (above). DS913DB2 5 CDB35L00-X4 1.6 Differential Analog Inputs The differential audio inputs into the four CS35L00 devices are provided by the 3-pin headers (J10, J20, J30, and J40) through DC blocking capacitors (C11, C12, C21, C22, C31, C32, C41, C42). The DC blocking capacitors allow for an analog source to connect directly to the CS35L00, regardless of any DC bias that may be present between the analog audio source's outputs and the CS35L00 inputs. 1.7 Speaker Outputs The four CS35L00 power outputs pairs are each configured for a single, full-bridge, audio channel. The outputs are routed through an optional EMI output filter and then presented at the J11, J21, J31, and J41 headers. The CS35L00 is intended to be used with a 4 to 8 load. 1.7.1 Optional Speaker Output EMI Filter Components The CDB35L00-X4 contains optional placeholders for a series ferrite bead (FB11, FB12, FB21, FB22, FB31, FB32, FB41, FB42) and shunt capacitor (C16, C17, C26, C27, C36, C37, C46, C47) output filter. For most applications with very short speaker leads between the CS35L00 and the speaker, use of these components will not be necessary. However, for systems with long signal paths between the CS35L00 and the speaker or if the system requires connecting to cables off the PCB, it is suggested that the ferrite bead and capacitor are populated with the recommended values shown in Table 6 on page 10. These optional output filters will reduce EMI between the CS35L00 speaker outputs and the load. In order to use the optional output filter ferrite beads for U1, the traces between the FB11 pads and the traces between the FB12 pads must be cut to break the bypass circuit, before populating FB11 and FB12 with the desired component values. The location of these required cuts are shown in below in Figure 3. The optional output filter ferrite beads for U2, U3, and U4 can be added in the same manner as described for U1 (above). The optional output filter capacitors can be populated with or without the addition of the ferrite beads and require no board modifications. Cut the bypass traces before inserting the optional input gain adjustment resistors Cut the bypass traces before inserting the optional output filter ferrite beads Figure 3. Optional Bypass Trace Cut Locations for U1 6 DS913DB2 CDB35L00-X4 2. GROUNDING AND POWER SUPPLY DECOUPLING The CS35L00 requires careful attention to power supply and grounding arrangements to optimize performance and minimize radiated emissions. The device decoupling capacitors should be located as close to the CS35L00 as possible. This can be optimized by using both top and bottom side component population as demonstrated by the CDB35L00-X4 board. 2.1 Power Supply Decoupling Proper power supply decoupling is one key to maximizing the performance of a Class-D amplifier. Figure 5 and Figure 6 on page 11 show the component placement for the CDB35L00-X4 board. Note the addition of the C13, C23, C33, and C43 capacitors connected to the LFILT+ pin. This pin is used as decoupling for the internal LDO regulator when operating in HD or FHD modes. The small value decoupling capacitors are placed as close as possible to the power pins of the CS35L00 on the CDB35L00-X4 board. It is recommended that the power supply decoupling capacitors reside on the opposite side of the board from which the CS35L00 is populated on. This allows for very close placement of the decoupling capacitors to the power supply pins of the CS35L00 without interfering with the differential audio inputs or differential audio outputs. This placement keeps the high-frequency current loop small to minimize EMI. 2.2 Electromagnetic Interference (EMI) This reference design is a board-level solution that is meant to control emissions by minimizing and suppressing them at the source, in contrast to containing them in an enclosure. 2.2.1 Suppression of EMI at the Source Several techniques are used in the circuit design and board layout to minimize high-frequency fields in the immediate vicinity of the high-power components. Specific techniques include the following: * As mentioned in Section 2.1, effective power supply decoupling of high-frequency currents and minimizing the loop area of the decoupling loop is one aspect of minimizing EMI. * Differential input and output signals should be routed differentially whenever possible. * A solid ground plane on the adjacent PCB layer underneath all high-frequency traces to minimize the loop area of the return path. * Optional output EMI filter component landings are available as described in Section 1.7.1, if emissions need to be further reduced. * Keeping the switching output filter components as close to the amplifier as possible. DS913DB2 7 CDB35L00-X4 3. SYSTEM CONNECTORS AND JUMPERS Connector Name VBATT GND GND IN1IN1+ OUT1OUT1+ GND IN2IN2+ OUT2OUT2+ GND IN3IN3+ OUT3OUT3+ GND IN4IN4+ OUT4OUT4+ Reference Designator J1 J1 J10 J10 J10 J11 J11 J20 J20 J20 J21 J21 J30 J30 J30 J31 J31 J40 J40 J40 J41 J41 Pin 1 2 1 2 3 1 2 1 2 3 1 2 1 2 3 1 2 1 2 3 1 2 Signal Direction Input Input GND Input Input Output Output GND Input Input Output Output GND Input Input Output Output GND Input Input Output Output Connector Function Positive connection from power supply, +2.5 to +5.5 VDC GND connection from power supply. GND reference connection Differential analog input (-) to CS35L00, U1 Differential analog input (+) to CS35L00, U1. Analog output (-) from CS35L00, U1 Analog output (+) from CS35L00, U1. GND reference connection Differential analog input (-) to CS35L00, U2 Differential analog input (+) to CS35L00, U2. Analog output (-) from CS35L00, U2 Analog output (+) from CS35L00, U2. GND reference connection Differential analog input (-) to CS35L00, U3 Differential analog input (+) to CS35L00, U3. Analog output (-) from CS35L00, U3 Analog output (+) from CS35L00, U3. GND reference connection Differential analog input (-) to CS35L00, U4 Differential analog input (+) to CS35L00, U4. Analog output (-) from CS35L00, U4 Analog output (+) from CS35L00, U4. Table 4. System Input and Output Connections S1 Control Name GAIN MODE SD1-2 SD3-4 Function Gain U1-U4 Mode U1-U4 Shutdown U1 & U2 Shutdown U3 & U4 Function Selected Low = CS35L00 gain set to +12 dB High = CS35L00 gain set to +6 dB Low = CS35L00 frequency reduced operational mode (FSD or FHD) High = CS35L00 non-frequency reduced operational mode (SD or HD) Low = CS35L00 shutdown enabled High = CS35L00 shutdown disabled Low = CS35L00 shutdown enabled High = CS35L00 shutdown disabled Table 5. S1 Switch Settings 8 DS913DB2 CDB35L00-X4 4. CDB SCHEMATIC Figure 4. CDB35L00-X4 Schematic DS913DB2 9 CDB35L00-X4 4.1 Bill of Materials The component listing below is shown for the CDB35L00-X4 board. Unpopulated (DNP) components are listed with recommended components for reference purposes. Qty 1 8 4 4 4 2 8 4 4 1 (DNP) (DNP) (DNP) Reference Designator(s) C3 C11, C12, C21, C22, C31, C32, C41, C42 C13, C23, C33, C43 C15, C25, C35, C45 C14, C24, C34, C44 R5, R6 R1, R2, R3, R4, R13, R23, R33, R43 R10, R20, R30, R40 U1, U2, U3, U4 S1 C16, C17, C26, C27, C36, C37, C46, C47 FB11, FB12, FB21, FB22, FB31, FB32, FB41, FB42 R11, R12, R21, R22, R31, R32, R41, R42 Description Capacitor, 1 F, X5R, 10V Capacitor, 0.1 F, X7R, 16V Capacitor, 1 F, X5R, 10V Capacitor, 10 F, X5R, 6.3 V Capacitor, 0.1 F, X7R, 16V Resistor, 4.7 k, 1/10W Resistor, 0 , 1/16W Resistor, 47 k, 1/16W Hybrid Class-D DFN Amp Switch, 4 POS, DIP Capacitor, 1 nF, X7R, 50V Ferrite Bead, 220 @ 100MHz Resistor, 0 , 1/16W MFG / Part Number Kemet / C0603C105K8PAC Kemet / C0402C104K4RAC Kemet / C0603C105K8PAC Kemet / C0603C106M9PAC Kemet / C0402C104K4RAC Dale / CRCW06034K70JNEA Yageo / RC0402JR-070RL Dale / CRCW040247K0JNED Cirrus Logic / CS35L00-CWZ Grayhill / 76SB04T Murata / GRM155R71H102KA01D TDK / MPZ1608S221A Yageo / RC0402JR-070RL Table 6. Bill of Materials Listing 10 DS913DB2 CDB35L00-X4 5. CDB LAYOUT Figure 5. CDB35L00-X4 Top Side Component Placement Figure 6. CDB35L00-X4 Bottom Side Component Placement Figure 7. CDB35L00-X4 Layer 1 Copper Figure 8. CDB35L00-X4 Layer 2 Copper Figure 9. CDB35L00-X4 Layer 3 Copper Figure 10. CDB35L00-X4 Layer 4 Copper DS913DB2 11 CDB35L00-X4 6. REVISION HISTORY Release DB1 DB2 - - - - Initial Release Updated 10% output power numbers on the front page to match DS906A2 device datasheet. Updated Figure 4 on page 9 to match the updated CDB35L00-X4 Rev A1 schematic. Updated BOM values for C6 & C7 in Table 6 on page 10 to match the udpated Rev A1 schematics and the typical connection diagram in the DS906A2 device datasheet. All CDB35L00-X4 boards with an assembly date of 02/15/10 or earlier contain components from the Rev A0 BOM. Changes Contacting Cirrus Logic Support For all product questions and inquiries, contact a Cirrus Logic Sales Representative. To find the one nearest to you, go to www.cirrus.com. IMPORTANT NOTICE Cirrus Logic, Inc. and its subsidiaries ("Cirrus") believe that the information contained in this document is accurate and reliable. However, the information is subject to change without notice and is provided "AS IS" without warranty of any kind (express or implied). Customers are advised to obtain the latest version of relevant information to verify, before placing orders, that information being relied on is current and complete. All products are sold subject to the terms and conditions of sale supplied at the time of order acknowledgment, including those pertaining to warranty, indemnification, and limitation of liability. No responsibility is assumed by Cirrus for the use of this information, including use of this information as the basis for manufacture or sale of any items, or for infringement of patents or other rights of third parties. This document is the property of Cirrus and by furnishing this information, Cirrus grants no license, express or implied under any patents, mask work rights, copyrights, trademarks, trade secrets or other intellectual property rights. Cirrus owns the copyrights associated with the information contained herein and gives consent for copies to be made of the information only for use within your organization with respect to Cirrus integrated circuits or other products of Cirrus. This consent does not extend to other copying such as copying for general distribution, advertising or promotional purposes, or for creating any work for resale. CERTAIN APPLICATIONS USING SEMICONDUCTOR PRODUCTS MAY INVOLVE POTENTIAL RISKS OF DEATH, PERSONAL INJURY, OR SEVERE PROPERTY OR ENVIRONMENTAL DAMAGE ("CRITICAL APPLICATIONS"). CIRRUS PRODUCTS ARE NOT DESIGNED, AUTHORIZED OR WARRANTED FOR USE IN PRODUCTS SURGICALLY IMPLANTED INTO THE BODY, AUTOMOTIVE SAFETY OR SECURITY DEVICES, LIFE SUPPORT PRODUCTS OR OTHER CRITICAL APPLICATIONS. INCLUSION OF CIRRUS PRODUCTS IN SUCH APPLICATIONS IS UNDERSTOOD TO BE FULLY AT THE CUSTOMER'S RISK AND CIRRUS DISCLAIMS AND MAKES NO WARRANTY, EXPRESS, STATUTORY OR IMPLIED, INCLUDING THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR PARTICULAR PURPOSE, WITH REGARD TO ANY CIRRUS PRODUCT THAT IS USED IN SUCH A MANNER. IF THE CUSTOMER OR CUSTOMER'S CUSTOMER USES OR PERMITS THE USE OF CIRRUS PRODUCTS IN CRITICAL APPLICATIONS, CUSTOMER AGREES, BY SUCH USE, TO FULLY INDEMNIFY CIRRUS, ITS OFFICERS, DIRECTORS, EMPLOYEES, DISTRIBUTORS AND OTHER AGENTS FROM ANY AND ALL LIABILITY, INCLUDING ATTORNEYS' FEES AND COSTS, THAT MAY RESULT FROM OR ARISE IN CONNECTION WITH THESE USES. Cirrus Logic, Cirrus, and the Cirrus Logic logo designs are trademarks of Cirrus Logic, Inc. All other brand and product names in this document may be trademarks or service marks of their respective owners. 12 DS913DB2 |
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