PRELIMINARY CYW43364 Single-Chip IEEE 802.11 b/g/n MAC/ Baseband/Radio The Cypress CYW43364 is a highly integrated single-chip solution and offers the lowest RBOM in the industry for Internet of Things (IoT) and a wide range of other portable devices. The chip includes a 2.4 GHz WLAN IEEE 802.11 b/g/n MAC/baseband/radio. In addition, it integrates a power amplifier (PA) that meets the output power requirements of most handheld systems, a low-noise amplifier (LNA) for best-in-class receiver sensitivity, and an internal transmit/receive (iTR) RF switch, further reducing the overall solution cost and printed circuit board area. The WLAN host interface supports gSPI and SDIO v2.0 modes, providing a raw data transfer rate up to 200 Mbps when operating in 4-bit mode at a 50 MHz bus frequency. Using advanced design techniques and process technology to reduce active and idle power, the CYW43364 is designed to address the needs of highly mobile devices that require minimal power consumption and compact size. It includes a power management unit that simplifies the system power topology while maximizing battery life. Cypress Part Numbering Scheme Cypress is converting the acquired IoT part numbers from Broadcom to the Cypress part numbering scheme. Due to this conversion, there is no change in form, fit, or function as a result of offering the device with Cypress part number marking. The table provides Cypress ordering part number that matches an existing IoT part number. Table 1. Mapping Table for Part Number between Broadcom and Cypress Broadcom Part Number Cypress Part Number BCM43364 CYW43364 BCM43364KUBG CYW43364KUBG BCM43364KUBGT CYW43364KUBGT Acronyms and Abbreviations In most cases, acronyms and abbreviations are defined on first use. For a comprehensive list of acronyms and other terms used in Cypress documents, go to http://www.cypress.com/glossary. Figure 1. CYW43364 System Block Diagram VDDIO VBAT WL_REG_ON WLAN Host I/F WL_HOST_WAKE SDIO*/SPI 2.4 GHz WLAN TX/RX BPF CYW43364 CLK_REQ REF_CLK (19.2, 26, or 37.4 MHz) Cypress Semiconductor Corporation Document Number: 002-14781 Rev. *C • 198 Champion Court • San Jose, CA 95134-1709 • 408-943-2600 Revised Friday, November 18, 2016 PRELIMINARY CYW43364 Features IEEE 802.11x Key Features ■ Single-band 2.4 GHz IEEE 802.11b/g/n. ■ ® ■ Support for 2.4 GHz Cypress TurboQAM data rates (256QAM) and 20 MHz channel bandwidth. ■ Integrated iTR switch supports a single 2.4 GHz antenna. ■ Supports explicit IEEE 802.11n transmit beamforming. ■ Tx and Rx low-density parity check (LDPC) support for improved range and power efficiency. ■ Supports standard SDIO v2.0 and gSPI host interfaces. ■ Supports space-time block coding (STBC) in the receiver. ■ Integrated ARM Cortex-M3 processor and on-chip memory for complete WLAN subsystem functionality, minimizing the need to wake up the applications processor for standard WLAN functions. This allows for further minimization of power consumption, while maintaining the ability to field-upgrade with future features. On-chip memory includes 512 KB SRAM and 640 KB ROM. OneDriver™ software architecture for easy migration from existing embedded WLAN. General Features ■ Support diversity antenna. ■ ■ Supports a battery voltage range from 3.0V to 4.8V with an internal switching regulator. 4 Kbit one-time programmable (OTP) memory for storing board parameters. ■ Can be routed on low-cost 1-x-1 PCB stack-ups. ■ Programmable dynamic power management. ■ 74-ball WLBGA package (4.87 mm × 2.87 mm, 0.4 mm pitch). ■ Security: ❐ WPA and WPA2 (Personal) support for powerful encryption and authentication. ❐ AES in WLAN hardware for faster data encryption and IEEE 802.11i compatibility. ❐ Reference WLAN subsystem provides Cisco Compatible Extensions (CCX, CCX 2.0, CCX 3.0, CCX 4.0, CCX 5.0). ❐ ■ Reference WLAN subsystem provides Wi-Fi protected setup (WPS). Worldwide regulatory support: Global products supported with worldwide homologated design. IoT Resources Cypress provides a wealth of data at http://www.cypress.com/internet-things-iot to help you to select the right IoT device for your design, and quickly and effectively integrate the device into your design. Cypress provides customer access to a wide range of information, including technical documentation, schematic diagrams, product bill of materials, PCB layout information, and software updates. Customers can acquire technical documentation and software from the Cypress Support Community website (http://community.cypress.com/). Document Number: 002-14781 Rev. *C Page 2 of 68 PRELIMINARY CYW43364 Contents 1. Overview ........................................................................ 4 1.1 Overview ............................................................... 4 1.2 Features ................................................................ 5 1.3 Standards Compliance .......................................... 5 2. Power Supplies and Power Management ................... 6 2.1 Power Supply Topology ........................................ 6 2.2 CYW43364 PMU Features .................................... 6 2.3 WLAN Power Management ................................... 9 2.4 PMU Sequencing .................................................. 9 2.5 Power-Off Shutdown ........................................... 10 2.6 Power-Up/Power-Down/Reset Circuits ............... 10 3. Frequency References ............................................... 11 3.1 Crystal Interface and Clock Generation .............. 11 3.2 TCXO .................................................................. 12 3.3 External 32.768 kHz Low-Power Oscillator ......... 13 4. WLAN System Interfaces ........................................... 14 4.1 SDIO v2.0 ............................................................ 14 4.2 Generic SPI Mode ............................................... 15 5. Wireless LAN MAC and PHY ..................................... 24 5.1 MAC Features ..................................................... 24 5.2 PHY Description .................................................. 26 6. WLAN Radio Subsystem ............................................ 28 6.1 Receive Path ....................................................... 28 6.2 Transmit Path ...................................................... 28 6.3 Calibration ........................................................... 28 7. CPU and Global Functions ........................................ 29 7.1 WLAN CPU and Memory Subsystem .................. 29 7.2 One-Time Programmable Memory ...................... 29 7.3 GPIO Interface .................................................... 29 7.4 External Coexistence Interface ........................... 30 7.5 JTAG Interface ................................................... 32 7.6 UART Interface ................................................... 32 8. Pinout and Signal Descriptions ................................ 33 8.1 Ball Map .............................................................. 33 8.2 WLBGA Ball List in Ball Number Order with X-Y Coordinates ................................................. 34 8.3 WLBGA Ball List Ordered By Ball Name ............. 37 8.4 Signal Descriptions .............................................. 38 Document Number: 002-14781 Rev. *C 8.5 WLAN GPIO Signals and Strapping Options ...... 41 8.6 Chip Debug Options ............................................ 41 8.7 I/O States ............................................................ 42 9. DC Characteristics ..................................................... 44 9.1 Absolute Maximum Ratings ................................. 44 9.2 Environmental Ratings ........................................ 44 9.3 Electrostatic Discharge Specifications ................ 45 9.4 Recommended Operating Conditions and DC Characteristics ............................................. 45 10. WLAN RF Specifications .......................................... 47 10.1 2.4 GHz Band General RF Specifications ......... 47 10.2 WLAN 2.4 GHz Receiver Performance Specifications ................................................... 48 10.3 WLAN 2.4 GHz Transmitter Performance Specifications ................................................... 51 10.4 General Spurious Emissions Specifications ...... 52 11. Internal Regulator Electrical Specifications .......... 53 11.1 Core Buck Switching Regulator ......................... 53 11.2 3.3V LDO (LDO3P3) ......................................... 54 11.3 CLDO ................................................................ 55 11.4 LNLDO .............................................................. 56 12. System Power Consumption ................................... 57 12.1 WLAN Current Consumption ............................. 57 13. Interface Timing and AC Characteristics ............... 58 13.1 SDIO Default Mode Timing ............................... 58 13.2 SDIO High-Speed Mode Timing ........................ 59 13.3 gSPI Signal Timing ............................................ 60 13.4 JTAG Timing ..................................................... 61 14. Power-Up Sequence and Timing ............................. 62 14.1 Sequencing of Reset and Regulator Control Signals .............................................................. 62 15. Package Information ................................................ 63 15.1 Package Thermal Characteristics ..................... 63 16. Mechanical Information ........................................... 64 17. Ordering Information ................................................ 66 Document History .......................................................... 67 Page 3 of 68 PRELIMINARY CYW43364 1. Overview 1.1 Overview The Cypress CYW43364 provides the highest level of integration for IoT and wireless automation system, with integrated IEEE 802.11 b/g/n. It provides a small form-factor solution with minimal external components to drive down cost for mass volumes and allows for handheld device flexibility in size, form, and function. The CYW43364 is designed to address the needs of highly mobile devices that require minimal power consumption and reliable operation. Figure 2 on page 4 shows the interconnection of all the major physical blocks in the CYW43364 and their associated external interfaces, which are described in greater detail in subsequent sections. SDP ETM Cortex M3 JTAG* Figure 2. CYW43364 Block Diagram Debug AHB Bus Matrix AHB AHB to APB Bridge RAM ROM APB Patch WD Timer InterCtrl SW Timer DMA Bus Arb ARM IP GPIO Ctrl JTAG supported over SDIO SDIO or gSPI Power Supply Sleep CLK XTAL WL_REG_ON Common and Radio Digital SWREG LDOx2 PMU Control SDIO LPO XTAL OSC. POR ARM CM3 Supported over SDIO Radio 2.4 GHz JTAG* MAC BTWLAN ECI GPIO UART UART IEEE 802.11a/b/g/n ROM OTP GPIO Backplane RAM WDT LNPPHY JTAG* gSPI 2.4 GHz PA LNA BPF WLAN Document Number: 002-14781 Rev. *C Page 4 of 68 PRELIMINARY CYW43364 1.2 Features The CYW43364 supports the following WLAN features: ■ IEEE 802.11b/g/n single-band radio with an internal power amplifier, LNA, and T/R switch ■ On-chip WLAN driver execution capable of supporting IEEE 802.11 functionality ■ WLAN host interface options: SDIO v2.0, including default and high-speed timing. ❐ gSPI—up to a 50 MHz clock rate ❐ 1.3 Standards Compliance The CYW43364 supports the following standards: ■ IEEE 802.11n—Handheld Device Class (Section 11) ■ IEEE 802.11b ■ IEEE 802.11g ■ IEEE 802.11d ■ IEEE 802.11h ■ IEEE 802.11i The CYW43364 will support the following future drafts/standards: ■ IEEE 802.11r — Fast Roaming (between APs) ■ IEEE 802.11k — Resource Management ■ IEEE 802.11w — Secure Management Frames ■ IEEE 802.11 Extensions: ■ IEEE 802.11e QoS Enhancements (as per the WMM specification is already supported) ■ IEEE 802.11i MAC Enhancements ■ IEEE 802.11r Fast Roaming Support ■ IEEE 802.11k Radio Resource Measurement The CYW43364 supports the following security features and proprietary protocols: ■ Security: ❐ WEP ❐ WPA Personal ❐ WPA2 Personal ❐ WMM ❐ WMM-PS (U-APSD) ❐ WMM-SA ❐ WAPI ❐ AES (Hardware Accelerator) ❐ TKIP (host-computed) ❐ CKIP (SW Support) ■ Proprietary Protocols: ❐ CCXv2 ❐ CCXv3 ❐ CCXv4 ❐ CCXv5 ■ IEEE 802.15.2 Coexistence Compliance — on silicon solution compliant with IEEE 3-wire requirements. Document Number: 002-14781 Rev. *C Page 5 of 68 PRELIMINARY CYW43364 2. Power Supplies and Power Management 2.1 Power Supply Topology One Buck regulator, multiple LDO regulators, and a power management unit (PMU) are integrated into the CYW43364. All regulators are programmable via the PMU to simplify the power supply. A single VBAT (3.0V to 4.8V DC maximum) and VDDIO supply (1.8V to 3.3V) can be used, with all additional voltages being provided by the regulators in the CYW43364. The WL_REG_ON control signal is used to power up the regulators and take the respective circuit blocks out of reset. The CBUCK CLDO and LNLDO power up when any of the reset signals are deasserted. All regulators are powered down only when WL_REG_ON is deasserted. The CLDO and LNLDO can be turned on and off based on the dynamic demands of the digital baseband. The CYW43364 allows for an extremely low power-consumption mode by completely shutting down the CBUCK, CLDO, and LNLDO regulators. When in this state, LPLDO1 provides the CYW43364 with all required voltage, further reducing leakage currents. Notes: VBAT should be connected to the LDO_VDDBAT5V and SR_VDDBAT5V pins of the device. VDDIO should be connected to the SYS_VDDIO and WCC_VDDIO pins of the device. 2.2 CYW43364 PMU Features The PMU supports the following: ■ VBAT to 1.35Vout (170 mA nominal, 370 mA maximum) Core-Buck (CBUCK) switching regulator ■ VBAT to 3.3Vout (250 mA nominal, 450 mA maximum 800 mA peak maximum) LDO3P3 ■ 1.35V to 1.2Vout (100 mA nominal, 150 mA maximum) LNLDO ■ 1.35V to 1.2Vout (80 mA nominal, 200 mA maximum) CLDO with bypass mode for deep sleep ■ Additional internal LDOs (not externally accessible) ■ PMU internal timer auto-calibration by the crystal clock for precise wake-up timing from extremely low power-consumption mode. Figure 3 on page 7 and Figure 4 on page 8 show the typical power topology of the CYW43364. Document Number: 002-14781 Rev. *C Page 6 of 68 PRELIMINARY CYW43364 Figure 3. Typical Power Topology (1 of 2) SR_VDDBAT5V VBAT WL RF—TX Mixer and PA Mini PMU CYW43364 1.2V VBAT: Operational: 2.4V—4.8V Performance: 3.0V—4.8V Absolute Maximum: 5.5V VDDIO Operational: 1.8V—3.3V Core Buck Int_SR_VBAT Regulator Peak: 370 mA Avg: 170 mA (320 mA) VDD1P35 WL RF—LOGEN Internal RXLDO 10 mA (NMOS) 1.2V WL RF—RX LNA Internal ADCLDO 10 mA (NMOS) 1.2V WL RF—ADC REF Internal TXLDO 80 mA (PMOS) 1.2V WL RF—TX Internal AFELDO 80 mA (NMOS) 1.2V LDO_VDD_1P5 VBAT SR_PVSS 4.7 uF 0402 LNLDO (100 mA) 1.2V (40 mA) 600 @ 100 MHz VOUT_LNLDO 2.2 uF 0402 PMU_VSS WCC_VDDIO WL RF—AFE and TIA Mini PMU is placed in WL radio 2.2 uH 0603 SR_VBAT5V WCC_VDDIO 1.2V 1.35V SR_VLX SW1 GND Internal VCOLDO 80 mA (NMOS) LPLDO1 (5 mA) WLRF_XTAL_ VDD1P2 10 mA average, > 10 mA at start‐up WL RF—RFPLL PFD and MMD WL RF—XTAL 0.1 uF 0201 1.1V WLAN/CLB/Top, Always On VDDC1 1.3V, 1.2V, CL LDO or 0.95V Peak: 200 mA (AVS) Avg: 80 mA (Bypass in deep‐ VOUT_CLDO sleep) WL_REG_ON WL OTP VDDC2 2.2 uF 0402 WL Digital and PHY o_wl_resetb WL VDDM (SROMs & AOS) Supply ball Supply bump/pad Power switch Ground ball Ground bump/pad No power switch WLAN reset balls External to chip No dedicated power switch, but internal power‐ down modes and block‐specific power switches Document Number: 002-14781 Rev. *C Page 7 of 68 PRELIMINARY CYW43364 Figure 4. Typical Power Topology (2 of 2) CYW43364 1.8V, 2.5V, and 3.3V VBAT LDO_ VDDBAT5V VOUT_3P3 LDO3P3 with Back‐Power VOUT_3P3 Protection 4.7 uF (Peak 450‐800 mA 200 mA Average) 3.3V 0402 6.4 mA WL BBPLL/DFLL WL OTP 3.3V 480 to 800 mA WLRF_PA_VDD 1 uF 0201 WL RF—PA (2.4 GHz) 2.5V Cap‐less LNLDO (10 mA) 6.4 mA WL RF—ADC, AFE, LOGEN, LNA, NMOS Mini‐PMU LDOs Power switch External to chip No power switch Supply ball No dedicated power switch, but internal power‐ down modes and block‐specific power switches Document Number: 002-14781 Rev. *C Page 8 of 68 PRELIMINARY CYW43364 2.3 WLAN Power Management The CYW43364 has been designed with the stringent power consumption requirements of mobile devices in mind. All areas of the chip design are optimized to minimize power consumption. Silicon processes and cell libraries were chosen to reduce leakage current and supply voltages. Additionally, the CYW43364 integrated RAM is a high volatile memory with dynamic clock control. The dominant supply current consumed by the RAM is leakage current only. Additionally, the CYW43364 includes an advanced WLAN power management unit (PMU) sequencer. The PMU sequencer provides significant power savings by putting the CYW43364 into various power management states appropriate to the operating environment and the activities that are being performed. The power management unit enables and disables internal regulators, switches, and other blocks based on a computation of the required resources and a table that describes the relationship between resources and the time needed to enable and disable them. Power-up sequences are fully programmable. Configurable, free-running counters (running at the 32.768 kHz LPO clock) in the PMU sequencer are used to turn on/turn off individual regulators and power switches. Clock speeds are dynamically changed (or gated altogether) for the current mode. Slower clock speeds are used wherever possible. The CYW43364 WLAN power states are described as follows: ■ Active mode: All WLAN blocks in the CYW43364 are powered up and fully functional with active carrier sensing and frame transmission and receiving. All required regulators are enabled and put in the most efficient mode based on the load current. Clock speeds are dynamically adjusted by the PMU sequencer. ■ Doze mode: The radio, analog domains, and most of the linear regulators are powered down. The rest of the CYW43364 remains powered up in an IDLE state. All main clocks (PLL, crystal oscillator) are shut down to reduce active power to the minimum. The 32.768 kHz LPO clock is available only for the PMU sequencer. This condition is necessary to allow the PMU sequencer to wake up the chip and transition to Active mode. In Doze mode, the primary power consumed is due to leakage current. ■ Deep-sleep mode: Most of the chip, including analog and digital domains, and most of the regulators are powered off. Logic states in the digital core are saved and preserved to retention memory in the always-on domain before the digital core is powered off. To avoid lengthy hardware reinitialization, the logic states in the digital core are restored to their pre-deep-sleep settings when a wakeup event is triggered by an external interrupt, a host resume through the SDIO bus, or by the PMU timers. ■ Power-down mode: The CYW43364 is effectively powered off by shutting down all internal regulators. The chip is brought out of this mode by external logic re-enabling the internal regulators. 2.4 PMU Sequencing The PMU sequencer is used to minimize system power consumption. It enables and disables various system resources based on a computation of required resources and a table that describes the relationship between resources and the time required to enable and disable them. Resource requests can derive from several sources: clock requests from cores, the minimum resources defined in the ResourceMin register, and the resources requested by any active resource request timers. The PMU sequencer maps clock requests into a set of resources required to produce the requested clocks. Each resource is in one of the following four states: ■ enabled ■ disabled ■ transition_on ■ transition_off The timer value is 0 when the resource is enabled or disabled and nonzero during state transition. The timer is loaded with the time_on or time_off value of the resource when the PMU determines that the resource must be enabled or disabled. That timer decrements on each 32.768 kHz PMU clock. When it reaches 0, the state changes from transition_off to disabled or transition_on to enabled. If the time_on value is 0, the resource can transition immediately from disabled to enabled. Similarly, a time_off value of 0 indicates that the resource can transition immediately from enabled to disabled. The terms enable sequence and disable sequence refer to either the immediate transition or the timer load-decrement sequence. During each clock cycle, the PMU sequencer performs the following actions: ■ Computes the required resource set based on requests and the resource dependency table. ■ Decrements all timers whose values are nonzero. If a timer reaches 0, the PMU clears the ResourcePending bit for the resource and inverts the ResourceState bit. ■ Compares the request with the current resource status and determines which resources must be enabled or disabled. ■ Initiates a disable sequence for each resource that is enabled, no longer being requested, and has no powered-up dependents. ■ Initiates an enable sequence for each resource that is disabled, is being requested, and has all of its dependencies enabled. Document Number: 002-14781 Rev. *C Page 9 of 68 PRELIMINARY CYW43364 2.5 Power-Off Shutdown The CYW43364 provides a low-power shutdown feature that allows the device to be turned off while the host, and any other devices in the system, remain operational. When the CYW43364 is not needed in the system, VDDIO_RF and VDDC are shut down while VDDIO remains powered. This allows the CYW43364 to be effectively off while keeping the I/O pins powered so that they do not draw extra current from any other devices connected to the I/O. During a low-power shutdown state, provided VDDIO remains applied to the CYW43364, all outputs are tristated, and most input signals are disabled. Input voltages must remain within the limits defined for normal operation. This is done to prevent current paths or create loading on any digital signals in the system, and enables the CYW43364 to be fully integrated in an embedded device and to take full advantage of the lowest power-savings modes. When the CYW43364 is powered on from this state, it is the same as a normal power-up, and the device does not retain any information about its state from before it was powered down. 2.6 Power-Up/Power-Down/Reset Circuits The CYW43364 has two signals (see Table 2) that enable or disable the WLAN circuits and the internal regulator blocks, allowing the host to control power consumption. For timing diagrams of these signals and the required power-up sequences, see Section 14.: “Power-Up Sequence and Timing,” on page 62. Table 2. Power-Up/Power-Down/Reset Control Signals Signal WL_REG_ON Description This signal is used by the PMU to power-up the WLAN section. When this pin is high, the regulators are enabled and the WLAN section is out of reset. When this pin is low, the WLAN section is in reset. This pin has an internal 200 kΩ pull-down resistor that is enabled by default. It can be disabled through programming. Document Number: 002-14781 Rev. *C Page 10 of 68 PRELIMINARY CYW43364 3. Frequency References An external crystal is used for generating all radio frequencies and normal operation clocking. As an alternative, an external frequency reference driven by a temperature-compensated crystal oscillator (TCXO) signal may be used. No software settings are required to differentiate between the two. In addition, a low-power oscillator (LPO) is provided for lower power mode timing. 3.1 Crystal Interface and Clock Generation The CYW43364 can use an external crystal to provide a frequency reference. The recommended configuration for the crystal oscillator, including all external components, is shown in Figure 5. Consult the reference schematics for the latest configuration. Figure 5. Recommended Oscillator Configuration C WLRF_XTAL_XOP 12 – 27 pF C 12 – 27 pF R WLRF_XTAL_XON Note: Resistor value determined by crystal drive level. See reference schematics for details. The CYW43364 uses a fractional-N synthesizer to generate the radio frequencies, clocks, and data/packet timing so that it can operate using numerous frequency references. The frequency reference can be an external source such as a TCXO or a crystal interfaced directly to the CYW43364. The default frequency reference setting is a 37.4 MHz crystal or TCXO. The signal requirements and characteristics for the crystal interface are shown in Table 3 on page 12. Note: Although the fractional-N synthesizer can support many reference frequencies, frequencies other than the default require support to be added in the driver, plus additional extensive system testing. Contact Cypress for further details. Document Number: 002-14781 Rev. *C Page 11 of 68 PRELIMINARY CYW43364 3.2 TCXO As an alternative to a crystal, an external precision TCXO can be used as the frequency reference, provided that it meets the phase noise requirements listed in Table 3 on page 12. If the TCXO is dedicated to driving the CYW43364, it should be connected to the WLRF_XTAL_XOP pin through an external capacitor with value ranges from 200 pF to 1000 pF as shown in Figure 6. Figure 6. Recommended Circuit to Use with an External Dedicated TCXO 200 pF – 1000 pF TCXO WLRF_XTAL_XOP NC WLRF_XTAL_XON Table 3. Crystal Oscillator and External Clock Requirements and Performance Parameter External Frequency Reference Crystal Conditions/Notes Units Min. Typ. Max. Min. Typ. Max. Frequency – – 37.4a – – – – MHz Crystal load capacitance – – 12 – – – – pF ESR – – – 60 – – – Ω Input Impedance (WLRF_XTAL_XOP) Resistive – – – 10k 100k – Ω Capacitive – – – – – 7 pF WLRF_XTAL_XOP input voltage AC-coupled analog signal – – – 400b – 1260 mVp-p WLRF_XTAL_XOP input low level DC-coupled digital signal – – – 0 – 0.2 V WLRF_XTAL_XOP input high level DC-coupled digital signal – – – 1.0 – 1.26 V Frequency tolerance Initial + over temperature – –20 – 20 –20 – 20 ppm Duty cycle 37.4 MHz clock – – – 40 50 60 % Phase Noisec, d, e (IEEE 802.11 b/g) 37.4 MHz clock at 10 kHz offset – – – – – –129 dBc/Hz 37.4 MHz clock at 100 kHz offset – – – – – –136 dBc/Hz c, d, e Phase Noise (IEEE 802.11n, 2.4 GHz) 37.4 MHz clock at 10 kHz offset – – – – – –134 dBc/Hz 37.4 MHz clock at 100 kHz offset – – – – – –141 dBc/Hz Phase Noisec, d, e (256-QAM) 37.4 MHz clock at 10 kHz offset – – – – – –140 dBc/Hz 37.4 MHz clock at 100 kHz offset – – – – – –147 dBc/Hz a. b. c. d. e. The frequency step size is approximately 80 Hz. The CYW43364 does not auto-detect the reference clock frequency; the frequency is specified in the software and/or NVRAM file. To use 256-QAM, a 800 mV minimum voltage is required. For a clock reference other than 37.4 MHz, 20 × log10(f/37.4) dB should be added to the limits, where f = the reference clock frequency in MHz. Phase noise is assumed flat above 100 kHz. The CYW43364 supports a 26 MHz reference clock sharing option. See the phase noise requirement in the table. Document Number: 002-14781 Rev. *C Page 12 of 68 PRELIMINARY CYW43364 3.3 External 32.768 kHz Low-Power Oscillator The CYW43364 uses a secondary low-frequency sleep clock for low-power mode timing. Either the internal low-precision LPO or an external 32.768 kHz precision oscillator is required. The internal LPO frequency range is approximately 33 kHz ± 30% over process, voltage, and temperature, which is adequate for some applications. However, one trade-off caused by this wide LPO tolerance is a small current consumption increase during power save mode that is incurred by the need to wake up earlier to avoid missing beacons. Whenever possible, the preferred approach is to use a precision external 32.768 kHz clock that meets the requirements listed in Table 4 on page 13. Note: The CYW43364 will auto-detect the LPO clock. If it senses a clock on the EXT_SLEEP_CLK pin, it will use that clock. If it doesn't sense a clock, it will use its own internal LPO. ■ To use the internal LPO: Tie EXT_SLEEP_CLK to ground. Do not leave this pin floating. ■ To use an external LPO: Connect the external 32.768 kHz clock to EXT_SLEEP_CLK. Table 4. External 32.768 kHz Sleep-Clock Specifications Parameter LPO Clock Units Nominal input frequency 32.768 kHz Frequency accuracy ±200 ppm Duty cycle 30–70 % Input signal amplitude 200–3300 Signal type Square wave or sine wave Input impedancea Clock jitter >100 <5 <10,000 mV, p-p – kΩ pF ppm a. When power is applied or switched off. Document Number: 002-14781 Rev. *C Page 13 of 68 PRELIMINARY CYW43364 4. WLAN System Interfaces 4.1 SDIO v2.0 The CYW43364 WLAN section supports SDIO version 2.0. for both 1-bit (25 Mbps) and 4-bit modes (100 Mbps), as well as high speed 4-bit mode (50 MHz clocks—200 Mbps). It has the ability to map the interrupt signal on a GPIO pin. This out-of-band interrupt signal notifies the host when the WLAN device wants to turn on the SDIO interface. The ability to force control of the gated clocks from within the WLAN chip is also provided. SDIO mode is enabled using the strapping option pins. See Table 11 on page 41 for details. Three functions are supported: ■ Function 0 standard SDIO function. The maximum block size is 32 bytes. ■ Function 1 backplane function to access the internal System-on-a-Chip (SoC) address space. The maximum block size is 64 bytes. ■ Function 2 WLAN function for efficient WLAN packet transfer through DMA. The maximum block size is 512 bytes. 4.1.1 SDIO Pin Descriptions Table 5. SDIO Pin Descriptions SD 4-Bit Mode DATA0 Data line 0 DATA1 DATA2 DATA3 SD 1-Bit Mode gSPI Mode DATA Data line DO Data output Data line 1 or Interrupt IRQ Interrupt IRQ Interrupt Data line 2 NC Not used NC Not used Data line 3 NC Not used CLK Clock CLK Clock CMD Command line CMD Command line CS SCLK DI Card select Clock Data input Figure 7. Signal Connections to SDIO Host (SD 4-Bit Mode) CLK CMD SD Host CYW43364 DAT[3:0] Figure 8. Signal Connections to SDIO Host (SD 1-Bit Mode) CLK CMD CYW43364 SD Host DATA IRQ Document Number: 002-14781 Rev. *C Page 14 of 68 PRELIMINARY CYW43364 4.2 Generic SPI Mode In addition to the full SDIO mode, the CYW43364 includes the option of using the simplified generic SPI (gSPI) interface/protocol. Characteristics of the gSPI mode include: ■ Up to 50 MHz operation ■ Fixed delays for responses and data from the device ■ Alignment to host gSPI frames (16 or 32 bits) ■ Up to 2 KB frame size per transfer ■ Little-endian and big-endian configurations ■ A configurable active edge for shifting ■ Packet transfer through DMA for WLAN The gSPI mode is enabled using the strapping option pins. See Table 11 on page 41 for details. Figure 9. Signal Connections to SDIO Host (gSPI Mode) SCLK DI DO SD Host CYW43364 IRQ CS Document Number: 002-14781 Rev. *C Page 15 of 68 PRELIMINARY CYW43364 4.2.1 SPI Protocol The SPI protocol supports both 16-bit and 32-bit word operation. Byte endianess is supported in both modes. Figure 10 and Figure 11 on page 17 show the basic write and write/read commands. Figure 10. gSPI Write Protocol Document Number: 002-14781 Rev. *C Page 16 of 68 PRELIMINARY CYW43364 Figure 11. gSPI Read Protocol Document Number: 002-14781 Rev. *C Page 17 of 68 PRELIMINARY CYW43364 Command Structure The gSPI command structure is 32 bits. The bit positions and definitions are shown in Figure 12. Figure 12. gSPI Command Structure BCM_SPID Command Structure 31 30 29 28 27 C A 11 10 F1 F0 Address – 17 bits 0 Packet length - 11bits * * 11’h0 = 2048 bytes Function No: 00 – Func 0: 0 All SPI-specific registers 01 – Func 1: 1 Registers and memories belonging to other blocks in the chip (64 bytes max) 10 – Func 2: 2 DMA channel 1. WLAN packets up to 2048 bytes. 11 – Func 3: 3 DMA channel 2 (optional). Packets up to 2048 bytes. Access : 0 – Fixed address 1 – Incremental address Command : 0 – Read 1 – Write Write The host puts the first bit of the data onto the bus half a clock-cycle before the first active edge following the CS going low. The following bits are clocked out on the falling edge of the gSPI clock. The device samples the data on the active edge. Write/Read The host reads on the rising edge of the clock requiring data from the device to be made available before the first rising-clock edge of the data. The last clock edge of the fixed delay word can be used to represent the first bit of the following data word. This allows data to be ready for the first clock edge without relying on asynchronous delays. Read The read command always follows a separate write to set up the WLAN device for a read. This command differs from the write/read command in the following respects: a) chip selects go high between the command/address and the data, and b) the time interval between the command/address is not fixed. Document Number: 002-14781 Rev. *C Page 18 of 68 PRELIMINARY CYW43364 Status The gSPI interface supports status notification to the host after a read/write transaction. This status notification provides information about packet errors, protocol errors, available packets in the RX queue, etc. The status information helps reduce the number of interrupts to the host. The status-reporting feature can be switched off using a register bit, without any timing overhead. The gSPI bus timing for read/write transactions with and without status notification are as shown in Figure 13 below and Figure 14 on page 20. See Table 6 on page 20 for information on status-field details. Figure 13. gSPI Signal Timing Without Status Write CS SCLK MOSI C31 C31 C30 C30 C1 C1 C0 C0 D31 D31 D30 D30 Command 32 bits Write-Read D1 D1 D0 D0 Write Data 16*n bits CS SCLK MOSI C31 C31 C30 C30 C0 C0 MISO D31 D31 D30 D30 Response Delay Command 32 bits Read D1 D1 D0 D0 Read Data 16*n bits CS SCLK MOSI C31 C31 C30 C30 C0 C0 D31 D31 D30 D30 MISO Command 32 bits Document Number: 002-14781 Rev. *C Response Delay D0 D0 Read Data 16*n bits Page 19 of 68 PRELIMINARY CYW43364 Figure 14. gSPI Signal Timing with Status (Response Delay = 0) CS Write SCLK C31 C31 MOSI C1 C1 C0 C0 D31 D31 D1 D1 D0 D0 S31 S31 MISO Command 32 bits Write-Read Write Data 16*n bits S1 S1 S0 S0 Status 32 bits CS SCLK C31 C31 MOSI C0 C0 MISO D31 D31 D1 D1 D0 D0 S31 S31 Read Data 16*n bits Command 32 bits S0 S0 Status 32 bits CS Read SCLK MOSI C31 C31 C0 C0 MISO D31 D31 Command 32 bits D1 D1 D0 D0 S31 S31 Read Data 16*n bits S0 S0 Status 32 bits Table 6. gSPI Status Field Details Bit Name Description 0 Data not available The requested read data is not available. 1 Underflow FIFO underflow occurred due to current (F2, F3) read command. 2 Overflow FIFO overflow occurred due to current (F1, F2, F3) write command. 3 F2 interrupt F2 channel interrupt 5 F2 RX ready F2 FIFO is ready to receive data (FIFO empty). 7 Reserved – 8 9:19 F2 packet available Packet is available/ready in F2 TX FIFO. F2 packet length Length of packet available in F2 FIFO 4.2.2 gSPI Host-Device Handshake To initiate communication through the gSPI after power-up, the host needs to bring up the WLAN chip by writing to the wake-up WLAN register bit. Writing a 1 to this bit will start up the necessary crystals and PLLs so that the CYW43364 is ready for data transfer. The device can signal an interrupt to the host indicating that the device is awake and ready. This procedure also needs to be followed for waking up the device in sleep mode. The device can interrupt the host using the WLAN IRQ line whenever it has any information to pass to the host. On getting an interrupt, the host needs to read the interrupt and/or status register to determine the cause of the interrupt and then take necessary actions. Document Number: 002-14781 Rev. *C Page 20 of 68 PRELIMINARY CYW43364 4.2.3 Boot-Up Sequence After power-up, the gSPI host needs to wait 50 ms for the device to be out of reset. For this, the host needs to poll with a read command to F0 address 0x14. Address 0x14 contains a predefined bit pattern. As soon as the host gets a response back with the correct register content, it implies that the device has powered up and is out of reset. After that, the host needs to set the wake-up WLAN bit (F0 reg 0x00 bit 7). Wake-up WLAN turns the PLL on; however, the PLL doesn't lock until the host programs the PLL registers to set the crystal frequency. For the first time after power-up, the host needs to wait for the availability of the low-power clock inside the device. Once it is available, the host needs to write to a PMU register to set the crystal frequency. This will turn on the PLL. After the PLL is locked, the chipActive interrupt is issued to the host. This indicates device awake/ready status. See Table 7 for information on gSPI registers. In Table 7, the following notation is used for register access: ■ R: Readable from host and CPU ■ W: Writable from host ■ U: Writable from CPU Table 7. gSPI Registers Address x0000 Register Bit Access Default Word length 0 R/W/U 0 0: 16-bit word length 1: 32-bit word length Endianess 1 R/W/U 0 0: Little endian 1: Big endian High-speed mode 4 R/W/U 1 0: Normal mode. Sample on SPICLK rising edge, output on falling edge. 1: High-speed mode. Sample and output on rising edge of SPICLK (default). Interrupt polarity 5 R/W/U 1 0: Interrupt active polarity is low. 1: Interrupt active polarity is high (default). Wake-up 7 R/W 0 A write of 1 denotes a wake-up command from host to device. This will be followed by an F2 interrupt from the gSPI device to host, indicating device awake status. Status enable 0 R/W 1 0: No status sent to host after a read/write. 1: Status sent to host after a read/write. Interrupt with status 1 R/W 0 0: Do not interrupt if status is sent. 1: Interrupt host even if status is sent. Reserved – – – – 0 R/W 0 Requested data not available. Cleared by writing a 1 to this location. 1 R 0 F2/F3 FIFO underflow from the last read. 2 R 0 F2/F3 FIFO overflow from the last write. 5 R 0 F2 packet available 6 R 0 F3 packet available 7 R 0 F1 overflow from the last write. 5 R 0 F1 Interrupt 6 R 0 F2 Interrupt F3 Interrupt x0002 x0003 x0004 Interrupt register Description x0005 Interrupt register 7 R 0 x0006, x0007 Interrupt enable register 15:0 R/W/U 16'hE0E7 Particular interrupt is enabled if a corresponding bit is set. x0008 to x000B Status register 31:0 R 32'h0000 Same as status bit definitions Document Number: 002-14781 Rev. *C Page 21 of 68 PRELIMINARY CYW43364 Table 7. gSPI Registers (Cont.) Address Register Bit Access Default 0 R 1 F1 enabled Description 1 R 0 F1 ready for data transfer 13:2 R/U 12'h40 F1 maximum packet size 0 R/U 1 F2 enabled 1 R 0 F2 ready for data transfer 15:2 R/U 14'h800 F2 maximum packet size x000C, x000D F1 info. register x000E, x000F F2 info. register x0014 to x0017 Test Read-only register 31:0 R This register contains a predefined pattern, which the host 32'hFEEDBE can read to determine if the gSPI interface is working AD properly. x0018 to x001B Test R/W register 31:0 R/W/U This is a dummy register where the host can write some 32'h0000000 pattern and read it back to determine if the gSPI interface 0 is working properly. x001C to x001F Response delay registers R/W Individual response delays for F0, F1, F2, and F3. The 0x1D = 4, value of the registers is the number of byte delays that are other introduced before data is shifted out of the gSPI interface registers = 0 during host reads. 7:0 Figure 15 on page 23 shows the WLAN boot-up sequence from power-up to firmware download, including the initial device power-on reset (POR) evoked by the WL_REG_ON signal. After initial power-up, the WL_REG_ON signal can be held low to disable the CYW43364 or pulsed low to induce a subsequent reset. Note: The CYW43364 has an internal power-on reset (POR) circuit. The device will be held in reset for a maximum of 3 ms after VDDC and VDDIO have both passed the 0.6V threshold. Document Number: 002-14781 Rev. *C Page 22 of 68 PRELIMINARY CYW43364 Figure 15. WLAN Boot-Up Sequence Ramp time from 0V to 4.3V > 40 µs VBAT 0.6V VDDIO > 2 Sleep Clock cycles WL_REG_ON < 1.5 ms VDDC (from internal PMU) < 3 ms Internal POR < 50 ms After a fixed delay following internal POR going high, the device responds to host F0 (address 0x14) reads. Device requests a reference clock. 15 1 ms After 15 ms1 the reference clock is assumed to be up. Access to PLL registers is possible. SPI Host Interaction: Host polls F0 (address 0x14) until it reads a predefined pattern. Host sets wake-up-wlan bit and waits 15 ms1, the maximum time for reference clock availability. After 15 1 ms, the host programs the PLL registers to set the crystal frequency. Chip-active interrupt is asserted after the PLL locks. WL_IRQ Host downloads code. 1 This wait time is programmable in sleep-clock increments from 1 to 255 (30 µs to 15 ms). Document Number: 002-14781 Rev. *C Page 23 of 68 PRELIMINARY CYW43364 5. Wireless LAN MAC and PHY 5.1 MAC Features The CYW43364 WLAN MAC supports features specified in the IEEE 802.11 base standard, and amended by IEEE 802.11n. The salient features are listed below: ■ Transmission and reception of aggregated MPDUs (A-MPDU). ■ Support for power management schemes, including WMM power-save, power-save multipoll (PSMP) and multiphase PSMP operation. ■ Support for immediate ACK and Block-ACK policies. ■ Interframe space timing support, including RIFS. ■ Support for RTS/CTS and CTS-to-self frame sequences for protecting frame exchanges. ■ Back-off counters in hardware for supporting multiple priorities as specified in the WMM specification. ■ Timing synchronization function (TSF), network allocation vector (NAV) maintenance, and target beacon transmission time (TBTT) generation in hardware. ■ Hardware off-load for AES-CCMP, legacy WPA TKIP, legacy WEP ciphers, WAPI, and support for key management. ■ Programmable independent basic service set (IBSS) or infrastructure basic service set functionality ■ Statistics counters for MIB support. 5.1.1 MAC Description The CYW43364 WLAN MAC is designed to support high throughput operation with low-power consumption. In addition, several power-saving modes that have been implemented allow the MAC to consume very little power while maintaining network-wide timing synchronization. The architecture diagram of the MAC is shown in Figure 16 on page 24. Figure 16. WLAN MAC Architecture Embedded CPU Interface Host Registers, DMA Engines TX‐FIFO 32 KB PMQ RX‐FIFO 10 KB PSM PSM UCODE Memory IFS WEP WEP, TKIP, AES TSF SHM BUS IHR NAV BUS TXE TX A‐MPDU EXT‐ IHR MAC ‐ RXE RX A‐MPDU Shared Memory 6 KB PHY Interface The following sections provide an overview of the important modules in the MAC. Document Number: 002-14781 Rev. *C Page 24 of 68 PRELIMINARY CYW43364 PSM The programmable state machine (PSM) is a microcoded engine that provides most of the low-level control to the hardware to implement the IEEE 802.11 specification. It is a microcontroller that is highly optimized for flow-control operations, which are predominant in implementations of communication protocols. The instruction set and fundamental operations are simple and general, which allows algorithms to be optimized until very late in the design process. It also allows for changes to the algorithms to track evolving IEEE 802.11 specifications. The PSM fetches instructions from the microcode memory. It uses the shared memory to obtain operands for instructions, as a data store, and to exchange data between both the host and the MAC data pipeline (via the SHM bus). The PSM also uses a scratch-pad memory (similar to a register bank) to store frequently accessed and temporary variables. The PSM exercises fine-grained control over the hardware engines by programming internal hardware registers (IHR). These IHRs are collocated with the hardware functions they control and are accessed by the PSM via the IHR bus. The PSM fetches instructions from the microcode memory using an address determined by the program counter, an instruction literal, or a program stack. For ALU operations, the operands are obtained from shared memory, scratch-pad memory, IHRs, or instruction literals, and the results are written into the shared memory, scratch-pad memory, or IHRs. There are two basic branch instructions: conditional branches and ALU-based branches. To better support the many decision points in the IEEE 802.11 algorithms, branches can depend on either readily available signals from the hardware modules (branch condition signals are available to the PSM without polling the IHRs) or on the results of ALU operations. WEP The wired equivalent privacy (WEP) engine encapsulates all the hardware accelerators to perform the encryption and decryption, as well as the MIC computation and verification. The accelerators implement the following cipher algorithms: legacy WEP, WPA TKIP, and WPA2 AES-CCMP. Based on the frame type and association information, the PSM determines the appropriate cipher algorithm to be used. It supplies the keys to the hardware engines from an on-chip key table. The WEP interfaces with the transmit engine (TXE) to encrypt and compute the MIC on transmit frames and the receive engine (RXE) to decrypt and verify the MIC on receive frames. WAPI is also supported. TXE The transmit engine (TXE) constitutes the transmit data path of the MAC. It coordinates the DMA engines to store the transmit frames in the TXFIFO. It interfaces with WEP module to encrypt frames and transfers the frames across the MAC-PHY interface at the appropriate time determined by the channel access mechanisms. The data received from the DMA engines are stored in transmit FIFOs. The MAC supports multiple logical queues to support traffic streams that have different QoS priority requirements. The PSM uses the channel access information from the IFS module to schedule a queue from which the next frame is transmitted. Once the frame is scheduled, the TXE hardware transmits the frame based on a precise timing trigger received from the IFS module. The TXE module also contains the hardware that allows the rapid assembly of MPDUs into an A-MPDU for transmission. The hardware module aggregates the encrypted MPDUs by adding appropriate headers and pad delimiters as needed. RXE The receive engine (RXE) constitutes the receive data path of the MAC. It interfaces with the DMA engine to drain the received frames from the RX FIFO. It transfers bytes across the MAC-PHY interface and interfaces with the WEP module to decrypt frames. The decrypted data is stored in the RX FIFO. The RXE module contains programmable filters that are programmed by the PSM to accept or filter frames based on several criteria such as receiver address, BSSID, and certain frame types. The RXE module also contains the hardware required to detect A-MPDUs, parse the headers of the containers, and disaggregate them into component MPDUS. IFS The IFS module contains the timers required to determine interframe space timing including RIFS timing. It also contains multiple back-off engines required to support prioritized access to the medium as specified by WMM. The interframe spacing timers are triggered by the cessation of channel activity on the medium, as indicated by the PHY. These timers provide precise timing to the TXE to begin frame transmission. The TXE uses this information to send response frames or perform transmit frame-bursting (RIFS or SIFS separated, as within a TXOP). The back-off engines (for each access category) monitor channel activity, in each slot duration, to determine whether to continue or pause the back-off counters. When the back-off counters reach 0, the TXE gets notified so that it may commence frame transmission. In the event of multiple back-off counters decrementing to 0 at the same time, the hardware resolves the conflict based on policies provided by the PSM. Document Number: 002-14781 Rev. *C Page 25 of 68 PRELIMINARY CYW43364 The IFS module also incorporates hardware that allows the MAC to enter a low-power state when operating under the IEEE powersaving mode. In this mode, the MAC is in a suspended state with its clock turned off. A sleep timer, whose count value is initialized by the PSM, runs on a slow clock and determines the duration over which the MAC remains in this suspended state. Once the timer expires, the MAC is restored to its functional state. The PSM updates the TSF timer based on the sleep duration, ensuring that the TSF is synchronized to the network. TSF The timing synchronization function (TSF) module maintains the TSF timer of the MAC. It also maintains the target beacon transmission time (TBTT). The TSF timer hardware, under the control of the PSM, is capable of adopting timestamps received from beacon and probe response frames in order to maintain synchronization with the network. The TSF module also generates trigger signals for events that are specified as offsets from the TSF timer, such as uplink and downlink transmission times used in PSMP. NAV The network allocation vector (NAV) timer module is responsible for maintaining the NAV information conveyed through the duration field of MAC frames. This ensures that the MAC complies with the protection mechanisms specified in the standard. The hardware, under the control of the PSM, maintains the NAV timer and updates the timer appropriately based on received frames. This timing information is provided to the IFS module, which uses it as a virtual carrier-sense indication. MAC-PHY Interface The MAC-PHY interface consists of a data path interface to exchange RX/TX data from/to the PHY. In addition, there is a programming interface, which can be controlled either by the host or the PSM to configure and control the PHY. 5.2 PHY Description The CYW43364 WLAN digital PHY is designed to comply with IEEE 802.11b/g/n single stream to provide wireless LAN connectivity supporting data rates from 1 Mbps to 96 Mbps for low-power, high-performance handheld applications. The PHY has been designed to meet specification requirements in the presence of interference, radio nonlinearity, and impairments. It incorporates efficient implementations of the filters, FFT, and Viterbi decoder algorithms. Efficient algorithms have been designed to achieve maximum throughput and reliability, including algorithms for carrier sense/rejection, frequency/phase/timing acquisition and tracking, and channel estimation and tracking. The PHY receiver also contains a robust IEEE 802.11b demodulator. The PHY carrier sense has been tuned to provide high throughput for IEEE 802.11g/IEEE 802.11b hybrid networks. 5.2.1 PHY Features ■ Supports the IEEE 802.11b/g/n single-stream standards. ■ Supports explicit IEEE 802.11n transmit beamforming. ■ Supports optional Greenfield mode in TX and RX. ■ Tx and Rx LDPC for improved range and power efficiency. ■ Supports IEEE 802.11h/d for worldwide operation. ■ Algorithms achieving low power, enhanced sensitivity, range, and reliability. ■ Automatic gain control scheme for blocking and nonblocking application scenarios for cellular applications. ■ Closed-loop transmit power control. ■ Designed to meet FCC and other regulatory requirements. ■ Support for 2.4 GHz Cypress TurboQAM data rates and 20 MHz channel bandwidth. Document Number: 002-14781 Rev. *C Page 26 of 68 PRELIMINARY CYW43364 Figure 17. WLAN PHY Block Diagram Filters and Radio Comp AFE and Radio Radio Control Block CCK/DSSS Demodulate Frequency and Timing Synch Carrier Sense, AGC, and Rx FSM Tx FSM OFDM Demodulate Buffers Viterbi Decoder Descramble and Deframe MAC Interface FFT/IFFT Modulation and Coding Frame and Scramble Filters and Radio Comp PA Comp Modulate/ Spread COEX The PHY is capable of fully calibrating the RF front-end to extract the highest performance. On power-up, the PHY performs a full calibration suite to correct for IQ mismatch and local oscillator leakage. The PHY also performs periodic calibration to compensate for any temperature related drift, thus maintaining high-performance over time. A closed-loop transmit control algorithm maintains the output power at its required level and can control TX power on a per-packet basis. Document Number: 002-14781 Rev. *C Page 27 of 68 PRELIMINARY CYW43364 6. WLAN Radio Subsystem The CYW43364 includes an integrated WLAN RF transceiver that has been optimized for use in 2.4 GHz Wireless LAN systems. It is designed to provide low power, low cost, and robust communications for applications operating in the globally available 2.4 GHz unlicensed ISM band. The transmit and receive sections include all on-chip filtering, mixing, and gain control functions. Improvements to the radio design include shared TX/RX baseband filters and high immunity to supply noise. Figure 18 shows the radio functional block diagram. Figure 18. Radio Functional Block Diagram WL DAC WL TXLPF WL PA WL DAC WL PGA WL TX G‐Mixer WL TXLPF Voltage Regulators WLAN BB 4 ~ 6 nH Recommend Q = 40 WLRF_2G_RF WL ADC 10 pF WL RXLPF WLRF_2G_eLG SLNA WL ADC WL G‐LNA12 WL RX G‐Mixer WL RXLPF CLB WL ATX WL ARX WL GTX WL GRX WL LOGEN WL PLL 6.1 Receive Path The CYW43364 has a wide dynamic range, direct conversion receiver. It employs high-order on-chip channel filtering to ensure reliable operation in the noisy 2.4 GHz ISM band. 6.2 Transmit Path Baseband data is modulated and upconverted to the 2.4 GHz ISM band. A linear on-chip power amplifier is included, which is capable of delivering high output powers while meeting IEEE 802.11b/g/n specifications without the need for an external PA. This PA is supplied by an internal LDO that is directly supplied by VBAT, thereby eliminating the need for a separate PALDO. Closed-loop output power control is integrated. 6.3 Calibration The CYW43364 features dynamic on-chip calibration, eliminating process variation across components. This enables the CYW43364 to be used in high-volume applications because calibration routines are not required during manufacturing testing. These calibration routines are performed periodically during normal radio operation. Automatic calibration examples include baseband filter calibration for optimum transmit and receive performance and LOFT calibration for leakage reduction. In addition, I/Q calibration, R calibration, and VCO calibration are performed on-chip. Document Number: 002-14781 Rev. *C Page 28 of 68 PRELIMINARY CYW43364 7. CPU and Global Functions 7.1 WLAN CPU and Memory Subsystem The CYW43364 includes an integrated ARM Cortex-M3 processor with internal RAM and ROM. The ARM Cortex-M3 processor is a low-power processor that features low gate count, low interrupt latency, and low-cost debugging. It is intended for deeply embedded applications that require fast interrupt response features. The processor implements the ARM architecture v7-M with support for the Thumb-2 instruction set. ARM Cortex-M3 provides a 30% performance gain over ARM7TDMI. At 0.19 µW/MHz, the Cortex-M3 is the most power efficient general purpose microprocessor available, outperforming 8- and 16-bit devices on MIPS/µW. It supports integrated sleep modes. ARM Cortex-M3 uses multiple technologies to reduce cost through improved memory utilization, reduced pin overhead, and reduced silicon area. ARM Cortex-M3 supports independent buses for code and data access (ICode/DCode and system buses). ARM CortexM3 supports extensive debug features including real-time tracing of program execution. On-chip memory for the CPU includes 512 KB SRAM and 640 KB ROM. 7.2 One-Time Programmable Memory Various hardware configuration parameters may be stored in an internal 4096-bit One-Time Programmable (OTP) memory, which is read by system software after a device reset. In addition, customer-specific parameters, including the system vendor ID and the MAC address, can be stored, depending on the specific board design. The initial state of all bits in an unprogrammed OTP device is 0. After any bit is programmed to a 1, it cannot be reprogrammed to 0. The entire OTP array can be programmed in a single write cycle using a utility provided with the Cypress WLAN manufacturing test tools. Alternatively, multiple write cycles can be used to selectively program specific bytes, but only bits which are still in the 0 state can be altered during each programming cycle. Prior to OTP memory programming, all values should be verified using the appropriate editable nvram.txt file, which is provided with the reference board design package. Documentation on the OTP development process is available on the Cypress customer support portal (http://community.cypress.com/). 7.3 GPIO Interface Five general-purpose I/O (GPIO) pins are available on the CYW43364 that can be used to connect to various external devices. GPIOs are tristated by default. Subsequently, they can be programmed to be either input or output pins via the GPIO control register. They can also be programmed to have internal pull-up or pull-down resistors. GPIO_0 is normally used as a WL_HOST_WAKE signal. The CYW43364 supports 2-wire, 3-wire, and 4-wire coexistence configurations using GPIO_1 through GPIO_4. The signal functions of GPIO_1 through GPIO_4 are programmable to support the three coexistence configurations. Document Number: 002-14781 Rev. *C Page 29 of 68 PRELIMINARY CYW43364 7.4 External Coexistence Interface The CYW43364 supports 2-wire, 3-wire, and 4-wire coexistence interfaces to enable signaling between the device and an external colocated wireless device in order to manage wireless medium sharing for optimal performance. The external colocated device can be any of the following ICs: GPS, WiMAX, LTE, or UWB. An LTE IC is used in this section for illustration. 7.4.1 2-Wire Coexistence Figure 19 shows a 2-wire LTE coexistence example. The following definitions apply to the GPIOs in the figure: ■ GPIO_1: WLAN_SECI_TX output to an LTE IC. ■ GPIO_2: WLAN_SECI_RX input from an LTE IC. Figure 19. 2-Wire Coexistence Interface to an LTE IC GPIO_1 GPIO_2 CYW43364 WLAN_SECI_TX WLAN_SECI_RX UART_IN UART_OUT LTE/IC Note: WLAN_SECI_OUT and WLAN_SECI_IN are multiplexed on the GPIOs. Document Number: 002-14781 Rev. *C Page 30 of 68 PRELIMINARY CYW43364 7.4.2 3-Wire and 4-Wire Coexistence Interfaces Figure 20 and Figure 21 show 3-wire and 4-wire LTE coexistence examples, respectively. The following definitions apply to the GPIOs in the figures: ■ For the 3-wire coexistence interface: ■ GPIO_2: WLAN priority output to an LTE IC. ■ GPIO_3: LTE_RX input from an LTE IC. ■ GPIO_4: LTE_TX input from an LTE IC. For the 4-wire coexistence interface: ■ GPIO_1: WLAN priority output to an LTE IC. ■ GPIO_2: LTE frame sync input from an LTE IC. This GPIO applies only to the 4-wire coexistence interface. ■ GPIO_3: LTE_RX input from an LTE IC. ■ GPIO_4: LTE_TX input from an LTE IC. Figure 20. 3-Wire Coexistence Interface to an LTE IC GPIO_2 WLAN Priority GPIO_3 LTE_RX GPIO_4 LTE_TX CYW43364 LTE/IC Figure 21. 4-Wire Coexistence Interface to an LTE IC CYW43364 Document Number: 002-14781 Rev. *C GPIO_1 WLAN Priority GPIO_2 LTE_Frame_Sync GPIO_3 LTE_RX GPIO_4 LTE_TX LTE/IC Page 31 of 68 PRELIMINARY CYW43364 7.5 JTAG Interface The CYW43364 supports the IEEE 1149.1 JTAG boundary scan standard over SDIO for performing device package and PCB assembly testing during manufacturing. In addition, the JTAG interface allows Cypress to assist customers by using proprietary debug and characterization test tools during board bring-up. Therefore, it is highly recommended to provide access to the JTAG pins by means of test points or a header on all PCB designs. 7.6 UART Interface One UART interface can be enabled by software as an alternate function on the JTAG pins. UART_RX is available on the JTAG_TDI pin, and UART_TX is available on the JTAG_TDO pin. The UART is primarily for debugging during development. By adding an external RS-232 transceiver, this UART enables the CYW43364 to operate as RS-232 data termination equipment (DTE) for exchanging and managing data with other serial devices. It is compatible with the industry standard 16550 UART, and it provides a FIFO size of 64 × 8 in each direction. Document Number: 002-14781 Rev. *C Page 32 of 68 PRELIMINARY CYW43364 8. Pinout and Signal Descriptions 8.1 Ball Map Figure 22 shows the 74-ball WLBGA ball map. Figure 22. 74-Ball WLBGA Ball Map (Bottom View) A B C 1 NC NC NC 2 NC NC NC 3 NC NC 4 NC 5 NC 6 SR_VLX 7 SR_PVSS A D E F G H NC VDD_1P2 VDD_1P2 VDDB_PA NC VDD_1P2 VDD_1P2 VSS VSS WLRF_GE WLRF_VD WLRF_LNA WLRF_PA_ NERAL_GN D_ _GND GND D 1P35 NC VDDC VSS VSS WLRF_GPI O NC NC VSSC NC SYS_VDDI O NC PMU_AVS VOUT_CLD VOUT_LNL S O DO SR_VDDB LDO_VDD1 AT5V P5 B Document Number: 002-14781 Rev. *C C D NC GND J VDDC WLRF_AFE _GND LPO_IN NC NC VSSC GPIO_1 GPIO_0 VOUT_3P3 LDO_VDD BAT5V E F GPIO_3 GPIO_4 H J M WLRF_PA_ 1 VDD WLRF_VC O_GND 2 WLRF_XTA L_ 3 VDD1P2 WLRF_XTA WLRF_XTA 4 L_GND L_XOP GPIO_2 WLRF_XTA 5 L_XON SDIO_DAT SDIO_CMD CLK_REQ A_0 SDIO_DAT SDIO_DAT A_1 A_3 G L WLRF_2G_ WLRF_2G_ eLG RF NC WCC_VDDI WL_REG_ O ON K 6 SDIO_DAT SDIO_CLK 7 A_2 K L M Page 33 of 68 PRELIMINARY CYW43364 8.2 WLBGA Ball List in Ball Number Order with X-Y Coordinates Table 8 provides ball numbers and names in ball number order. The table includes the X and Y coordinates for a top view with a (0,0) center. Table 8. CYW43364 WLBGA Ball List — Ordered By Ball Number Ball Number Ball Name X Coordinate Y Coordinate A1 NC –1200.006 2199.996 A2 NC –799.992 2199.996 A3 NC –399.996 2199.996 A4 NC 0 2199.996 A5 NC 399.996 2199.996 A6 SR_VLX 799.992 2199.978 A7 SR_PVSS 1199.988 2199.978 B1 NC –1200.006 1800 B2 NC –799.992 1800 B3 NC –399.996 1800 B4 NC 0 1800 B5 NC 399.996 1800 B6 PMU_AVSS 799.992 1799.982 B7 SR_VBAT5V 1199.988 1799.982 C1 NC –1200.006 1399.995 C2 NC –799.992 1399.986 C3 NC –399.996 1399.995 C4 NC 0 1399.995 C5 SYS_VDDIO 399.996 1399.986 C6 VOUT_CLDO 799.992 1399.986 C7 LDO_VDD15V 1199.988 1399.986 D2 NC –799.992 999.99 D3 VDDC –399.996 999.999 D4 VSSC 0 999.999 D5 NC 399.996 999.99 D6 VOUT_LNLDO 799.992 999.99 E1 NC –1199.988 599.994 E2 VDD_1P2 –799.992 599.994 E3 VSS –399.996 599.994 E5 NC 399.996 599.994 E6 GND 799.992 599.994 E7 VOUT_3P3 1199.988 599.994 F1 VDD_1P2 –1199.988 199.998 F2 VDD_1P2 –799.992 199.998 Document Number: 002-14781 Rev. *C Page 34 of 68 PRELIMINARY CYW43364 Table 8. CYW43364 WLBGA Ball List — Ordered By Ball Number Ball Number Ball Name X Coordinate Y Coordinate 0 199.998 F4 NC F5 LPO_IN 399.996 199.998 F6 WCC_VDDIO 800.001 199.998 F7 LDO_VBAT5V 1199.988 199.998 G1 VDD_1P2 –1199.988 –199.998 G2 VSS –799.992 –199.998 G4 VDDC 0 –199.998 G5 NC 399.996 –199.998 G6 WL_REG_ON 800.001 –199.998 H1 VDDB_PA –1199.988 –599.994 H2 VSS –799.992 –599.994 H3 VSS –399.996 –599.994 H4 WLRF_AFE_GND 0 –599.994 H5 NC 399.996 –599.994 H6 GPIO_1 800.001 –599.994 H7 SDIO_DATA_1 1200.006 –599.994 J1 WLRF_2G_eLG –1199.988 –999.99 J2 WLRF_LNA_GND –799.992 –999.99 J3 WLRF_GPIO –399.996 –999.99 J5 VSSC 399.996 –999.999 J6 GPIO_0 800.001 –999.999 J7 SDIO_DATA_3 1200.006 –999.999 K1 WLRF_2G_RF –1199.988 –1399.986 K2 WLRF_GENERAL_GND –799.992 –1399.986 K4 GPIO_3 0 –1399.995 K5 GPIO_4 399.996 –1399.995 K6 SDIO_DATA_0 800.001 –1399.995 L2 WLRF_PA_GND –799.992 –1799.982 L3 WLRF_VCO_GND –399.996 –1799.982 L4 WLRF_XTAL_GND 0 –1799.982 L5 GPIO_2 399.996 –1799.991 L6 SDIO_CMD 800.001 –1799.991 L7 SDIO_DATA_2 1200.006 –1799.991 M1 WLRF_PA_VDD –1199.988 –2199.978 M2 WLRF_VDD_1P35 –799.992 –2199.978 M3 WLRF_XTAL_VDD1P2 –399.996 –2199.978 M4 WLRF_XTAL_XOP 0 –2199.978 M5 WLRF_XTAL_XON 399.996 –2199.978 Document Number: 002-14781 Rev. *C Page 35 of 68 PRELIMINARY CYW43364 Table 8. CYW43364 WLBGA Ball List — Ordered By Ball Number Ball Number Ball Name X Coordinate Y Coordinate M6 CLK_REQ 800.001 –2199.996 M7 SDIO_CLK 1200.006 –2199.996 Document Number: 002-14781 Rev. *C Page 36 of 68 PRELIMINARY CYW43364 8.3 WLBGA Ball List Ordered By Ball Name Table 9 provides the ball numbers and names in ball name order. Table 9. CYW43364 WLBGA Ball List — Ordered By Ball Name Ball Name Ball Number CLK_REQ M6 GND E6 GPIO_0 J6 GPIO_1 H6 GPIO_2 L5 GPIO_3 K4 GPIO_4 K5 LDO_VDD1P5 C7 LDO_VDDBAT5V F7 LPO_IN F5 NC A1 NC A2 NC A3 NC A4 NC A5 NC B1 NC B2 NC B3 NC B4 NC B5 NC C1 NC C2 NC C3 NC C4 NC D2 NC D5 NC E1 NC E5 NC F4 NC G5 NC H5 PMU_AVSS B6 SDIO_CLK M7 SDIO_CMD L6 SDIO_DATA_0 K6 SDIO_DATA_1 H7 SDIO_DATA_2 L7 Document Number: 002-14781 Rev. *C Ball Name SDIO_DATA_3 Ball Number J7 SR_PVSS A7 SR_VDDBAT5V B7 SR_VLX A6 SYS_VDDIO C5 VDD_1P2 E2 VDD_1P2 F1 VDD_1P2 F2 VDD_1P2 G1 VDDB_PA H1 VDDC D3 VDDC G4 VOUT_3P3 E7 VOUT_CLDO C6 VOUT_LNLDO D6 VSS E3 VSS G2 VSS H2 VSS H3 VSSC D4 VSSC J5 WCC_VDDIO F6 WL_REG_ON G6 WLRF_2G_eLG J1 WLRF_2G_RF K1 WLRF_AFE_GND H4 WLRF_GENERAL_GND K2 WLRF_GPIO J3 WLRF_LNA_GND J2 WLRF_PA_GND L2 WLRF_PA_VDD M1 WLRF_VCO_GND L3 WLRF_VDD_1P35 M2 WLRF_XTAL_GND L4 WLRF_XTAL_VDD1P2 M3 WLRF_XTAL_XON M5 WLRF_XTAL_XOP M4 Page 37 of 68 PRELIMINARY CYW43364 8.4 Signal Descriptions Table 10 provides the WLBGA package signal descriptions. Table 10. WLBGA Signal Descriptions Signal Name WLBGA Ball Type Description K1 O 2.4 GHz WLAN RF output port. M7 I SDIO clock input. RF Signal Interface WLRF_2G_RF SDIO Bus Interface SDIO_CLK SDIO_CMD L6 I/O SDIO command line. SDIO_DATA_0 K6 I/O SDIO data line 0. SDIO_DATA_1 H7 I/O SDIO data line 1. SDIO_DATA_2 L7 I/O SDIO data line 2. Also used as a strapping option (see Table 13 on page 42). SDIO_DATA_3 J7 I/O SDIO data line 3. Note: Per Section 6 of the SDIO specification, 10 to 100 kΩ pull-ups are required on the four DATA lines and the CMD line. This requirement must be met during all operating states by using external pull-up resistors or properly programming internal SDIO host pull-ups. WLAN GPIO Interface WLRF_GPIO J3 I/O Test pin. Not connected in normal operation. WLRF_XTAL_XON M5 O XTAL oscillator output. WLRF_XTAL_XOP M4 I XTAL oscillator input. O External system clock request—Used when the system clock is not provided by a dedicated crystal (for example, when a shared TCXO is used). Asserted to indicate to the host that the clock is required. F5 I External sleep clock input (32.768 kHz). If an external 32.768 kHz clock cannot be provided, pull this pin low. However, BLE will be always on and cannot go to deep sleep. A1 I No connect. Clocks CLK_REQ LPO_IN M6 No Connect NC_A1 NC_A2 A2 O No connect. NC_A3 A3 I/O No connect. NC_A4 A4 I/O No connect. NC_A5 A5 I/O No connect. NC_B1 B1 I/O No connect. NC_B2 B2 I No connect. NC_B3 B3 I/O No connect. NC_B4 B4 O No connect. NC_B5 B5 I/O No connect. NC_C1 C1 I/O No connect. NC_C2 C2 O No connect. Document Number: 002-14781 Rev. *C Page 38 of 68 PRELIMINARY CYW43364 Table 10. WLBGA Signal Descriptions (Cont.) Signal Name WLBGA Ball Type Description NC_C3 C3 O NC_C4 C4 I No connect. NC_D2 D2 O No connect. NC_E1 E1 I No connect. No connect. NC_F4 F4 I/O No connect. NC_G5 G5 I/O No connect. NC_H5 H5 I/O No connect. NC_E5 E5 N/A Not used. Do not connect to this pin. NC_D5 D5 N/A Not used. Do not connect to this pin. Miscellaneous WL_REG_ON G6 I Used by PMU to power up or power down the internal regulators used by the WLAN section. Also, when deasserted, this pin holds the WLAN section in reset. This pin has an internal 200 kΩ pull-down resistor that is enabled by default. It can be disabled through programming. GND_E6 E6 I Tie pin E6 to ground. GPIO_0 J6 I/O GPIO_1 H6 I/O Programmable GPIO pins. GPIO_2 L5 I/O Programmable GPIO pins. GPIO_3 K4 I/O Programmable GPIO pins. GPIO_4 K5 I/O Programmable GPIO pins. WLRF_2G_eLG J1 I Connect to an external inductor. See the reference schematic for details. SR_VDDBAT5V B7 I SR VBAT input power supply. SR_VLX A6 O CBUCK switching regulator output. See Table 22 on page 53 for details of the inductor and capacitor required on this output. LDO_VDDBAT5V F7 I LDO VBAT. LDO_VDD1P5 C7 I LNLDO input. VOUT_LNLDO D6 O Output of low-noise LNLDO. VOUT_CLDO C6 O Output of core LDO. VDDB_PA H1 I Connect to VOUT_3P3. VDD_1P2 G1 I Connect to VOUT_LNLDO. VDD_1P2 F2 I Connect to VOUT_LNLDO. Programmable GPIO pins. This pin becomes an output pin when it is used as WLAN_HOST_WAKE/ out-of-band signal. Integrated Voltage Regulators VDD_1P2 F1 I Connect to VOUT_LNLDO. VDD_1P2 E2 I Connect pin E2 to VOUT_LNLDO. WLRF_XTAL_VDD1P2 M3 I XTAL oscillator supply. WLRF_PA_VDD M1 I Power amplifier supply. WCC_VDDIO F6 I VDDIO input supply. Connect to VDDIO. Power Supplies Document Number: 002-14781 Rev. *C Page 39 of 68 PRELIMINARY CYW43364 Table 10. WLBGA Signal Descriptions (Cont.) Signal Name SYS_VDDIO WLRF_VDD_1P35 VDDC VOUT_3P3 WLBGA Ball Type Description C5 I VDDIO input supply. Connect to VDDIO. M2 I LNLDO input supply. D3, G4 I Core supply for WLAN. E7 O 3.3V output supply. See the reference schematic for details. Ground VSS_H2 H2 I Connect to ground. VSS_G2 G2 I Connect to ground. VSS_H3 H3 I Connect to ground. VSS_E3 E3 I Connect to ground. PMU_AVSS B6 I Quiet ground. SR_PVSS VSSC WLRF_AFE_GND A7 I Switcher-power ground. D4, J5 I Core ground for WLAN. H4 I AFE ground. WLRF_LNA_GND J2 I 2.4 GHz internal LNA ground. WLRF_GENERAL_GND K2 I Miscellaneous RF ground. WLRF_PA_GND L2 I 2.4 GHz PA ground. WLRF_VCO_GND L3 I VCO/LO generator ground. WLRF_XTAL_GND L4 I XTAL ground. Document Number: 002-14781 Rev. *C Page 40 of 68 PRELIMINARY CYW43364 8.5 WLAN GPIO Signals and Strapping Options The pins listed in Table 11 are sampled at power-on reset (POR) to determine the various operating modes. Sampling occurs a few milliseconds after an internal POR or deassertion of the external POR. After the POR, each pin assumes the GPIO or alternative function specified in the signal descriptions table. Each strapping option pin has an internal pull-up (PU) or pull-down (PD) resistor that determines the default mode. To change the mode, connect an external PU resistor to VDDIO or a PD resistor to ground using a 10 kΩ resistor or less. Note: Refer to the reference board schematics for more information. Table 11. GPIO Functions and Strapping Options Pin Name WLBGA Pin # Default SDIO_DATA_2 L7 1 Function Description WLAN host interface select This pin selects the WLAN host interface mode. The default is SDIO. For gSPI, pull this pin low. 8.6 Chip Debug Options The chip can be accessed for debugging via the JTAG interface, multiplexed on the SDIO_DATA_0 through SDIO_DATA_3 (and SDIO_CLK) I/O depending on the bootstrap state of GPIO_1 and GPIO_2. Table 12 shows the debug options of the device. Table 12. Chip Debug Options JTAG_SEL GPIO_2 GPIO_1 0 0 0 0 0 0 1 Document Number: 002-14781 Rev. *C Function SDIO I/O Pad Function Normal mode SDIO 1 JTAG over SDIO JTAG 1 SWD over GPIO_1/GPIO_2 SDIO Page 41 of 68 PRELIMINARY CYW43364 8.7 I/O States The following notations are used in Table 13: ■ I: Input signal ■ O: Output signal ■ I/O: Input/Output signal ■ PU = Pulled up ■ PD = Pulled down ■ NoPull = Neither pulled up nor pulled down Table 13. I/O States Name WL_REG_ON I/O Keeper Active Mode Low Power State/ Sleep (All Power Present) Power-down (WL_REG_ON=0 BT_REG_ON=don’t care) Out-of-Reset; (WL_REG_ON=1; BT_REG_ON=don’t care) (WL_REG_ON=0 and (WL_REG_ON=1 and BT_REG_ON=0) and BT_REG_ON=1) VDDIOs are Present and VDDIOs are Present Power Rail I N Input; PD (pull-down can Input; PD (pull-down can Input; PD (of 200K) be disabled) be disabled) Input; PD (200k) Input; PD (200k) – – CLK_REQ I/O Y Open drain or push-pull (programmable). Active high. Open drain or push-pull PD (programmable). Active high Open drain, active high. Open drain, active high. Open drain, active high. WCC_VDDIO SDIO_DATA_0 I/O N SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> PU SDIO MODE -> NoPull Input; PU WCC_VDDIO SDIO_DATA_1 I/O N SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> PU SDIO MODE -> NoPull Input; PU WCC_VDDIO SDIO_DATA_2 I/O N SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> PU SDIO MODE -> NoPull Input; PU WCC_VDDIO SDIO_DATA_3 I/O N SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> PU SDIO MODE -> NoPull Input; PU WCC_VDDIO SDIO_CMD I/O N SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> PU SDIO MODE -> NoPull Input; PU WCC_VDDIO SDIO_CLK I N SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull SDIO MODE -> NoPull Input WCC_VDDIO JTAG_SEL I Y PD PD High-Z, NoPull Input, PD PD Input, PD WCC_VDDIO Input, SDIO OOB Int, NoPull Active mode Input, NoPull WCC_VDDIO Input, PD Active mode Input, Strap, PD WCC_VDDIO Input, GCI GPIO[7], NoPull Active mode Input, Strap, NoPull WCC_VDDIO a GPIO_0 I/O Y TBD Active mode High-Z, NoPull GPIO_1 I/O Y TBD Active mode High-Z, NoPulla a GPIO_2 I/O Y TBD Active mode High-Z, NoPull GPIO_3 I/O Y TBD Active mode High-Z, NoPulla Input, GCI GPIO[0], PU Active mode Input, PU WCC_VDDIO Active mode a Input, GCI GPIO[1], PU Active mode Input, PU WCC_VDDIO GPIO_4 I/O Y TBD Document Number: 002-14781 Rev. *C High-Z, NoPull Page 42 of 68 PRELIMINARY CYW43364 Table 13. I/O States (Cont.) Name I/O Keeper Active Mode Low Power State/ Sleep (All Power Present) Power-down (WL_REG_ON=0 BT_REG_ON=don’t care) Out-of-Reset; (WL_REG_ON=1; BT_REG_ON=don’t care) (WL_REG_ON=0 and (WL_REG_ON=1 and BT_REG_ON=0) and BT_REG_ON=1) VDDIOs are Present and VDDIOs are Present Power Rail Note: 1. Keeper column: N = pad has no keeper. Y = pad has a keeper. Keeper is always active except in the Power-down state. 2. If there is no keeper, and it is an input and there is Nopull, then the pad should be driven to prevent leakage due to a floating pad (e.g., SDIO_CLK). 3. In the Power-down state (xx_REG_ON = 0): High-Z; NoPull => The pad is disabled because power is not supplied. 4. Depending on whether the PCM interface is enabled and the configuration is master or slave mode, it can be either an output or input. 5. Depending on whether the I2S interface is enabled and the configuration is master or slave mode, it can be either an output or input. 6. The GPIO pull states for the Active and Low-Power states are hardware defaults. They can all be subsequently programmed as pull-ups or pull-downs. 7. Regarding GPIO pins, the following are the pull-up and pull-down values for both 3.3V and 1.8V VDDIO: 3.3V VDDIO pull-downs: 3.3V VDDIO pull-ups: 1.8V VDDIO pull-downs: 1.8V VDDIO pull-ups: Minimum (kΩ) 51.5 37.4 64 65 Typical (kΩ) 44.5 39.5 83 86 Maximum (kΩ) 38 44.5 116 118 a. The GPIO pull states for the active and low-power states are hardware defaults. They can all be subsequently programmed as a pull-up or pull-down. Document Number: 002-14781 Rev. *C Page 43 of 68 PRELIMINARY CYW43364 9. DC Characteristics Note: Values in this data sheet are design goals and are subject to change based on the results of device characterization. 9.1 Absolute Maximum Ratings Caution: The absolute maximum ratings in Table 14 indicate levels where permanent damage to the device can occur, even if these limits are exceeded for only a brief duration. Functional operation is not guaranteed under these conditions. Excluding VBAT, operation at the absolute maximum conditions for extended periods can adversely affect long-term reliability of the device. Table 14. Absolute Maximum Ratings Rating Symbol Value Unit DC supply for VBAT and PA driver supply VBAT –0.5 to +6.0a V DC supply voltage for digital I/O VDDIO –0.5 to 3.9 V DC supply voltage for RF switch I/Os VDDIO_RF –0.5 to 3.9 V DC input supply voltage for CLDO and LNLDO – –0.5 to 1.575 V DC supply voltage for RF analog VDDRF –0.5 to 1.32 V VDDC –0.5 to 1.32 V Vundershoot –0.5 V Vovershoot VDDIO + 0.5 V Tj 125 °C DC supply voltage for core Maximum undershoot voltage for I/O Maximum overshoot voltage for I/O b b Maximum junction temperature a. b. Continuous operation at 6.0V is supported. Duration not to exceed 25% of the duty cycle. 9.2 Environmental Ratings The environmental ratings are shown in Table 15. Table 15. Environmental Ratings Characteristic Units Conditions/Comments Ambient temperature (TA) –30 to +70°C a C Operation Storage temperature –40 to +125°C C – Less than 60 % Storage Less than 85 % Operation Relative humidity a. Value Functionality is guaranteed, but specifications require derating at extreme temperatures (see the specification tables for details). Document Number: 002-14781 Rev. *C Page 44 of 68 PRELIMINARY CYW43364 9.3 Electrostatic Discharge Specifications Extreme caution must be exercised to prevent electrostatic discharge (ESD) damage. Proper use of wrist and heel grounding straps to discharge static electricity is required when handling these devices. Always store unused material in its antistatic packaging. Table 16. ESD Specifications Pin Type Symbol ESD, Handling Reference: NQY00083, Section 3.4, Group ESD_HAND_HBM D9, Table B Machine Model (MM) CDM Condition ESD Rating Unit Human Body Model Contact Discharge per JEDEC EID/JESD22-A114 1250 V ESD_HAND_MM Machine Model Contact 50 V ESD_HAND_CDM Charged Device Model Contact Discharge per JEDEC EIA/JESD22C101 300 V 9.4 Recommended Operating Conditions and DC Characteristics Functional operation is not guaranteed outside the limits shown in Table 17, and operation outside these limits for extended periods can adversely affect long-term reliability of the device. Table 17. Recommended Operating Conditions and DC Characteristics Element DC supply voltage for VBAT DC supply voltage for core DC supply voltage for RF blocks in chip DC supply voltage for digital I/O DC supply voltage for RF switch I/Os External TSSI input Internal POR threshold SDIO Interface I/O Pins For VDDIO_SD = 1.8V: Input high voltage Input low voltage Output high voltage @ 2 mA Output low voltage @ 2 mA For VDDIO_SD = 3.3V: Input high voltage Input low voltage Output high voltage @ 2 mA Output low voltage @ 2 mA Other Digital I/O Pins For VDDIO = 1.8V: Input high voltage Input low voltage Output high voltage @ 2 mA Output low voltage @ 2 mA For VDDIO = 3.3V: Document Number: 002-14781 Rev. *C Symbol Value Unit Minimum 3.0a 1.14 1.14 Typical – 1.2 1.2 Maximum 4.8b 1.26 1.26 1.71 – 3.63 V 3.13 0.15 0.4 3.3 – – 3.46 0.95 0.7 V V V VIH VIL VOH VOL 1.27 – 1.40 – – – – – – 0.58 – 0.45 V V V V VIH VIL VOH VOL 0.625 × VDDIO – 0.75 × VDDIO – – – – – – 0.25 × VDDIO – 0.125 × VDDIO V V V V VIH VIL VOH VOL 0.65 × VDDIO – VDDIO – 0.45 – – – – – – 0.35 × VDDIO – 0.45 V V V V VBAT VDD VDDRF VDDIO, VDDIO_SD VDDIO_RF TSSI Vth_POR V V V Page 45 of 68 PRELIMINARY CYW43364 Table 17. Recommended Operating Conditions and DC Characteristics (Cont.) Element Input high voltage Input low voltage Output high voltage @ 2 mA Output low Voltage @ 2 mA RF Switch Control Output Pinsc For VDDIO_RF = 3.3V: Output high voltage @ 2 mA Output low voltage @ 2 mA Input capacitance a. b. c. Symbol Value VIH VIL VOH VOL Minimum 2.00 – VDDIO – 0.4 – Typical – – – – Maximum – 0.80 – 0.40 VOH VOL CIN VDDIO – 0.4 – – – – – – 0.40 5 Unit V V V V V V pF The CYW43364 is functional across this range of voltages. However, optimal RF performance specified in the data sheet is guaranteed only for 3.2V < VBAT < 4.8V. The maximum continuous voltage is 4.8V. Voltages up to 6.0V for up to 10 seconds, cumulative duration over the lifetime of the device are allowed. Voltages as high as 5.0V for up to 250 seconds, cumulative duration over the lifetime of the device are allowed. Programmable 2 mA to 16 mA drive strength. Default is 10 mA. Document Number: 002-14781 Rev. *C Page 46 of 68 PRELIMINARY CYW43364 10. WLAN RF Specifications The CYW43364 includes an integrated direct conversion radio that supports the 2.4 GHz band. This section describes the RF characteristics of the 2.4 GHz radio. Note: Values in this data sheet are design goals and may change based on device characterization results. Unless otherwise stated, the specifications in this section apply when the operating conditions are within the limits specified in Table 15 on page 44 and Table 17 on page 45. Functional operation outside these limits is not guaranteed. Typical values apply for the following conditions: ■ VBAT = 3.6V. ■ Ambient temperature +25°C. Figure 23. RF Port Location Chip Port C2 TX Filter Antenna Port 10 pF CYW43364 C1 L1 RX 4.7 nH 10 pF Note: All specifications apply at the chip port unless otherwise specified. 10.1 2.4 GHz Band General RF Specifications Table 18. 2.4 GHz Band General RF Specifications Item Condition Minimum Typical Maximum Unit TX/RX switch time Including TX ramp down – – 5 µs RX/TX switch time Including TX ramp up – – 2 µs Document Number: 002-14781 Rev. *C Page 47 of 68 PRELIMINARY CYW43364 10.2 WLAN 2.4 GHz Receiver Performance Specifications Note: Unless otherwise specified, the specifications in Table 19 are measured at the chip port (for the location of the chip port, see Figure 23 on page 47). Table 19. WLAN 2.4 GHz Receiver Performance Specifications Parameter Minimum Typical Maximum Unit – 2400 – 2500 MHz 1 Mbps DSSS –97.5 –99.5 – dBm –93.5 –95.5 – dBm –91.5 –93.5 – dBm 11 Mbps DSSS –88.5 –90.5 – dBm 6 Mbps OFDM –91.5 –93.5 – dBm 9 Mbps OFDM –90.5 –92.5 – dBm 12 Mbps OFDM –87.5 –89.5 – dBm RX sensitivity (10% PER for 1000 18 Mbps OFDM octet PSDU) at WLAN RF port a 24 Mbps OFDM –85.5 –87.5 – dBm –82.5 –84.5 – dBm 36 Mbps OFDM –80.5 –82.5 – dBm 48 Mbps OFDM –76.5 –78.5 – dBm 54 Mbps OFDM –75.5 –77.5 – dBm Frequency range Condition/Notes RX sensitivity (8% PER for 1024 2 Mbps DSSS octet PSDU) a 5.5 Mbps DSSS 20 MHz channel spacing for all MCS rates (Mixed mode) 256-QAM, R = 5/6 –67.5 –69.5 – dBm 256-QAM, R = 3/4 –69.5 –71.5 – dBm MCS7 –71.5 –73.5 – dBm RX sensitivity MCS6 (10% PER for 4096 octet PSDU). MCS5 Defined for default parameters: GF, 800 ns GI. MCS4 –73.5 –75.5 – dBm –74.5 –76.5 – dBm –79.5 –81.5 – dBm MCS3 –82.5 –84.5 – dBm MCS2 –84.5 –86.5 – dBm MCS1 –86.5 –88.5 – dBm MCS0 –90.5 –92.5 – dBm Document Number: 002-14781 Rev. *C Page 48 of 68 PRELIMINARY CYW43364 Table 19. WLAN 2.4 GHz Receiver Performance Specifications (Cont.) Parameter Condition/Notes Typical Maximum Unit 704–716 LTE – –13 – dBm 777–787 LTE – –13 – dBm 776–794 MHz CDMA2000 – –13.5 – dBm 815–830 LTE – –12.5 – dBm 816–824 CDMA2000 – –13.5 – dBm 816–849 LTE – –11.5 – dBm 824–849 WCDMA – –11.5 – dBm 824–849 CDMA2000 – –12.5 – dBm 824–849 LTE – –11.5 – dBm 824–849 GSM850 – –8 – dBm 830–845 LTE – –11.5 – dBm 832–862 LTE – –11.5 – dBm 880–915 WCDMA – –10 – dBm LTE – –12 – dBm E-GSM – –9 – dBm 1710–1755 WCDMA – –13 – dBm 1710–1755 LTE – –14.5 – dBm 1710–1755 CDMA2000 – –14.5 – dBm 1710–1785 WCDMA – –13 – dBm 1710–1785 LTE – –14.5 – dBm 1710–1785 GSM1800 – –12.5 – dBm 1850–1910 GSM1900 – –11.5 – dBm 1850–1910 CDMA2000 – –16 – dBm 1850–1910 WCDMA – –13.5 – dBm 1850–1910 LTE – –16 – dBm 1850–1915 LTE – –17 – dBm 1920–1980 WCDMA – –17.5 – dBm 1920–1980 CDMA2000 – –19.5 – dBm 1920–1980 LTE – –19.5 – dBm LTE – –44 – dBm LTE – –43 – dBm Blocking level for 3 dB Rx sensitivity degradation (without 880–915 external filtering) 880–915 Blocking level for 3 dB Rx sensi2300–2400 tivity degradation (without external filtering) 2500–2570 (cont.) 2570–2620 LTE – –34 – dBm WLAN – >–4 – dBm @ 1, 2 Mbps (8% PER, 1024 octets) –6 – – dBm @ 5.5, 11 Mbps (8% PER, 1024 octets) –12 – – dBm @ 6–54 Mbps (10% PER, 1000 octets) –15.5 – – dBm 5G (WLAN) Maximum receive level @ 2.4 GHz Minimum Document Number: 002-14781 Rev. *C Page 49 of 68 PRELIMINARY CYW43364 Table 19. WLAN 2.4 GHz Receiver Performance Specifications (Cont.) Parameter Condition/Notes Minimum Typical Maximum Unit Adjacent channel rejectionDSSS. (Difference between interfering and desired signal [25 MHz 11 Mbps DSSS apart] at 8% PER for 1024 octet PSDU with desired signal level as specified in Condition/Notes.) –70 dBm 35 – – dB 6 Mbps OFDM –79 dBm 16 – – dB 9 Mbps OFDM –78 dBm 15 – – dB 12 Mbps OFDM –76 dBm 13 – – dB 18 Mbps OFDM –74 dBm 11 – – dB 24 Mbps OFDM –71 dBm 8 – – dB 36 Mbps OFDM –67 dBm 4 – – dB 48 Mbps OFDM –63 dBm 0 – – dB 54 Mbps OFDM –62 dBm –1 – – dB 65 Mbps OFDM –61 dBm –2 – – dB Range –98 dBm to –75 dBm –3 – 3 dB Range above –75 dBm –5 – 5 dB Zo = 50Ω across the dynamic range. 10 – – dB Adjacent channel rejectionOFDM. (Difference between interfering and desired signal (25 MHz apart) at 10% PER for 1000b octet PSDU with desired signal level as specified in Condition/ Notes.) RCPI accuracyc Return loss a. b. c. Optimal RF performance, as specified in this data sheet, is guaranteed only for temperatures between –10°C and 55°C. For 65 Mbps, the size is 4096. The minimum and maximum values shown have a 95% confidence level. Document Number: 002-14781 Rev. *C Page 50 of 68 PRELIMINARY CYW43364 10.3 WLAN 2.4 GHz Transmitter Performance Specifications Note: Unless otherwise specified, the specifications in Table 19 are measured at the chip port (for the location of the chip port, see Figure 23 on page 47). Table 20. WLAN 2.4 GHz Transmitter Performance Specifications Parameter Frequency range Condition/Notes – Minimum Typical Maximum Unit 2400 – 2500 MHz 776–794 MHz CDMA2000 – –167.5 – dBm/Hz 869–960 MHz CDMAOne, GSM850 – –163.5 – dBm/Hz 1450–1495 DAB – –154.5 – dBm/Hz 1570–1580 MHz GPS – –152.5 – dBm/Hz 1592–1610 MHz GLONASS – –149.5 – dBm/Hz 1710–1800 DSC-1800-Uplink – –145.5 – dBm/Hz 1805–1880 MHz GSM 1800 – –143.5 – dBm/Hz 1850–1910 MHz GSM 1900 – –140.5 – dBm/Hz 1910–1930 MHz TDSCDMA,LTE – –138.5 – dBm/Hz 1930–1990 MHz GSM1900, CDMAOne, WCDMA – –139 – dBm/Hz 2010–2075 MHz TDSCDMA – –127.5 – dBm/Hz 2110–2170 MHz WCDMA – –124.5 – dBm/Hz 2305–2370 LTE Band 40 – –104.5 – dBm/Hz 2370–2400 LTE Band 40 – –81.5 – dBm/Hz 2496–2530 LTE Band 41 – –94.5 – dBm/Hz 2530–2560 LTE Band 41 – –120.5 – dBm/Hz 2570–2690 LTE Band 41 – –121.5 – dBm/Hz 5000–5900 WLAN 5G – –109.5 – dBm/Hz 4.8-5.0 GHz 2nd Harmonic – –26.5 – dBm/ MHz Harmonic level (at 21 dBm with 7.2-7.5 GHz 90% duty cycle, 1 Mbps CCK) 3rd Harmonic – –23.5 – dBm/ MHz 9.6-10 GHz 4th Harmonic – –32.5 – dBm/ MHz – – dBm Transmitted power in cellular and WLAN 5G band (at 21 dBm, 90% duty cycle, 1 Mbps CCK). EVM Does Not Exceed IEEE 802.11b (DSSS/CCK) –9 dB 21 OFDM, BPSK –8 dB 20.5 – – dBm –13 dB 20.5 – – dBm –19 dB 20.5 – – dBm –25 dB 18 – – dBm –27 dB 17.5 – – dBm 15 – – dBm TX power at the chip port for the OFDM, QPSK highest power level setting at OFDM, 16-QAM 25°C, VBA = 3.6V, and spectral mask and EVM compliancea, b OFDM, 64-QAM (R = 3/4) OFDM, 64-QAM (R = 5/6) OFDM, 256-QAM (R –32 dB = 5/6) Document Number: 002-14781 Rev. *C Page 51 of 68 PRELIMINARY CYW43364 Table 20. WLAN 2.4 GHz Transmitter Performance Specifications (Cont.) Parameter Condition/Notes Minimum Typical Maximum Unit – 9 – – dB Closed loop TX power variation Across full temperature and voltage range. at highest power level setting Applies across 5 to 21 dBm output power range. – – ±1.5 dB Carrier suppression – 15 – – dBc – – 0.25 – dB 4 6 – dB EVM degradation – 3.5 – dB Output power variation – ±2 – dB ACPR-compliant power level – 15 – dBm EVM degradation – 4 – dB Output power variation – ±3 – dB ACPR-compliant power level – 15 – dBm TX power control dynamic range Gain control step Return loss Zo = 50 VSWR = 2:1. Load pull variation for output power, EVM, and Adjacent Channel Power Ratio (ACPR) VSWR = 3:1. a. b. TX power for channel 1 and channel 11 is specified separately by nonvolatile memory parameters to ensure band-edge compliance. Optimal RF performance, as specified in this data sheet, is guaranteed only for temperatures between –10°C and 55°C. 10.4 General Spurious Emissions Specifications Table 21. General Spurious Emissions Specifications Parameter Condition/Notes Minimum Typical Maximum Unit – 2400 – 2500 MHz Frequency range General Spurious Emissions TX emissions RX/standby emissions 30 MHz < f < 1 GHz RBW = 100 kHz – –99 –96 dBm 1 GHz < f < 12.75 GHz RBW = 1 MHz – –44 –41 dBm 1.8 GHz < f < 1.9 GHz RBW = 1 MHz – –68 –65 dBm 5.15 GHz < f < 5.3 GHz RBW = 1 MHz – –88 –85 dBm 30 MHz < f < 1 GHz RBW = 100 kHz – –99 –96 dBm 1 GHz < f < 12.75 GHz RBW = 1 MHz – –54 –51 dBm 1.8 GHz < f < 1.9 GHz RBW = 1 MHz – –88 –85 dBm 5.15 GHz < f < 5.3 GHz RBW = 1 MHz – –88 –85 dBm Note: The specifications in this table apply at the chip port. Document Number: 002-14781 Rev. *C Page 52 of 68 PRELIMINARY CYW43364 11. Internal Regulator Electrical Specifications Note: Values in this data sheet are design goals and are subject to change based on device characterization results. Functional operation is not guaranteed outside of the specification limits provided in this section. 11.1 Core Buck Switching Regulator Table 22. Core Buck Switching Regulator (CBUCK) Specifications Specification Notes Input supply voltage (DC) DC voltage range inclusive of disturbances. PWM mode switching frequency CCM, load > 100 mA VBAT = 3.6V. Min. Typ. Max. 2.4 3.6 a Units 4.8 V – 4 – MHz PWM output current – – – 370 mA Output current limit – – 1400 – mA Output voltage range Programmable, 30 mV steps. Default = 1.35V. 1.2 1.35 1.5 V PWM output voltage DC accuracy Includes load and line regulation. Forced PWM mode. –4 – 4 % PWM ripple voltage, static Measure with 20 MHz bandwidth limit. Static load, max. ripple based on VBAT = 3.6V, Vout = 1.35V, Fsw = 4 MHz, 2.2 μH inductor L > 1.05 μH, Cap + Board total-ESR < 20 mΩ, Cout > 1.9 μF, ESL<200 pH – 7 20 mVpp PWM mode peak efficiency Peak efficiency at 200 mA load, inductor DCR = 200 mΩ, VBAT = 3.6V, VOUT = 1.35V – 85 – % PFM mode efficiency 10 mA load current, inductor DCR = 200 mΩ, VBAT = 3.6V, VOUT = 1.35V – 77 – % Start-up time from power down VDDIO already ON and steady. Time from REG_ON rising edge to CLDO reaching 1.2V – 400 500 µs External inductor 0603 size, 2.2 μH ±20%, DCR = 0.2Ω ± 25% – 2.2 – µH External output capacitor Ceramic, X5R, 0402, ESR <30 mΩ at 4 MHz, 4.7 μF ±20%, 10V 2.0b 4.7 10c µF External input capacitor For SR_VDDBATP5V pin, ceramic, X5R, 0603, ESR < 30 mΩ at 4 MHz, ±4.7 μF ±20%, 10V 0.67b 4.7 – µF Input supply voltage ramp-up time 0 to 4.3V 40 – – µs a. b. c. The maximum continuous voltage is 4.8V. Voltages up to 6.0V for up to 10 seconds, cumulative duration, over the lifetime of the device are allowed. Voltages as high as 5.0V for up to 250 seconds, cumulative duration, over the lifetime of the device are allowed. Minimum capacitor value refers to the residual capacitor value after taking into account the part-to-part tolerance, DC-bias, temperature, and aging. Total capacitance includes those connected at the far end of the active load. Document Number: 002-14781 Rev. *C Page 53 of 68 PRELIMINARY CYW43364 11.2 3.3V LDO (LDO3P3) Table 23. LDO3P3 Specifications Specification Input supply voltage, Vin Notes Min. Typ. Max. Units Min. = Vo + 0.2V = 3.5V dropout voltage requirement must be met under maximum load for performance specifications. 3.1 3.6 4.8a V – 0.001 – 450 mA – 3.3 – V Output current Nominal output voltage, Vo Default = 3.3V. Dropout voltage At max. load. – – 200 mV Output voltage DC accuracy Includes line/load regulation. –5 – +5 % Quiescent current No load – 66 85 µA Line regulation Vin from (Vo + 0.2V) to 4.8V, max. load – – 3.5 mV/V Load regulation load from 1 mA to 450 mA – – 0.3 mV/mA PSRR Vin ≥ Vo + 0.2V, Vo = 3.3V, Co = 4.7 µF, Max. load, 100 Hz to 100 kHz 20 – – dB LDO turn-on time Chip already powered up. – 160 250 µs External output capacitor, Co Ceramic, X5R, 0402, (ESR: 5 mΩ–240 mΩ), ± 10%, 10V 1.0b 4.7 5.64 µF External input capacitor For SR_VDDBATA5V pin (shared with band gap) Ceramic, X5R, 0402, (ESR: 30m-200 mΩ), ± 10%, 10V. Not needed if sharing VBAT capacitor 4.7 µF with SR_VDDBATP5V. – 4.7 – µF a. b. The maximum continuous voltage is 4.8V. Voltages up to 6.0V for up to 10 seconds, cumulative duration, over the lifetime of the device are allowed. Voltages as high as 5.0V for up to 250 seconds, cumulative duration, over the lifetime of the device are allowed. Minimum capacitor value refers to the residual capacitor value after taking into account the part-to-part tolerance, DC-bias, temperature, and aging. Document Number: 002-14781 Rev. *C Page 54 of 68 PRELIMINARY CYW43364 11.3 CLDO Table 24. CLDO Specifications Specification Input supply voltage, Vin Notes Min. = 1.2 + 0.15V = 1.35V dropout voltage requirement must be met under maximum load. Output current 7 Min. Typ. Max. Units 1.3 1.35 1.5 V 0.2 – 200 mA 0.95 1.2 1.26 V Output voltage, Vo Programmable in 10 mV steps. Default = 1.2.V Dropout voltage At max. load – – 150 mV Output voltage DC accuracy Includes line/load regulation –4 – +4 % No load – 13 – µA 200 mA load – 1.24 – mA Line regulation Vin from (Vo + 0.15V) to 1.5V, maximum load – – 5 mV/V Load regulation Load from 1 mA to 300 mA – 0.02 0.05 mV/mA Power down – 5 20 µA Bypass mode – 1 3 µA PSRR @1 kHz, Vin ≥ 1.35V, Co = 4.7 µF 20 – – dB Start-up time of PMU VDDIO up and steady. Time from the REG_ON rising edge to the CLDO reaching 1.2V. – – 700 µs LDO turn-on time LDO turn-on time when rest of the chip is up. – 140 180 µs External output capacitor, Co Total ESR: 5 mΩ–240 mΩ 1.1a 2.2 – µF External input capacitor Only use an external input capacitor at the VDD_LDO pin if it is not supplied from CBUCK output. – 1 2.2 µF Quiescent current Leakage current a. Minimum capacitor value refers to the residual capacitor value after taking into account the part-to-part tolerance, DC-bias, temperature, and aging. Document Number: 002-14781 Rev. *C Page 55 of 68 PRELIMINARY CYW43364 11.4 LNLDO Table 25. LNLDO Specifications Specification Notes Min. Typ. Max. Units Input supply voltage, Vin Min. VIN = VO + 0.15V = 1.35V (where VO = 1.2V) dropout voltage requirement must be met under maximum load. 1.3 1.35 1.5 V Output current – 0.1 – 150 mA Output voltage, Vo Programmable in 25 mV steps. Default = 1.2V 1.1 1.2 1.275 V Dropout voltage At maximum load – – 150 mV Output voltage DC accuracy Includes line/load regulation –4 – +4 % No load – 10 12 µA Max. load – 970 990 µA Line regulation Vin from (Vo + 0.15V) to 1.5V, 200 mA load – – 5 mV/V Load regulation Load from 1 mA to 200 mA: Vin ≥ (Vo + 0.12V) – 0.025 0.045 mV/mA Leakage current Power-down, junction temp. = 85°C – 5 20 µA Output noise @30 kHz, 60–150 mA load Co = 2.2 µF @100 kHz, 60–150 mA load Co = 2.2 µF – – 60 35 –nV/ Hz PSRR @1 kHz, Vin ≥ (Vo + 0.15V), Co = 4.7 µF 20 – – dB LDO turn-on time LDO turn-on time when rest of chip is up – 140 180 µs External output capacitor, Co Total ESR (trace/capacitor): 5 mΩ–240 mΩ 0.5a 2.2 4.7 µF External input capacitor Only use an external input capacitor at the VDD_LDO pin if it is not supplied from CBUCK output. Total ESR (trace/capacitor): 30 mΩ–200 mΩ – 1 2.2 µF Quiescent current a. Minimum capacitor value refers to the residual capacitor value after taking into account the part-to-part tolerance, DC-bias, temperature, and aging. Document Number: 002-14781 Rev. *C Page 56 of 68 PRELIMINARY CYW43364 12. System Power Consumption Note: The values in this data sheet are design goals and are subject to change based on device characterization.Unless otherwise stated, these values apply for the conditions specified in Table 17 on page 45. 12.1 WLAN Current Consumption Table 26 shows typical currents consumed by the CYW43364’s WLAN section. 12.1.1 2.4 GHz Mode Table 26. 2.4 GHz Mode WLAN Power Consumption Mode Rate VBAT = 3.6V, VDDIO = 1.8V, TA 25°C VBAT (mA) Vio (µA) N/A 0.0035 0.08 N/A 0.0058 80 Rate 1 0.0058 80 IEEE Power Save PM1 DTIM1 (Avg.) c Rate 1 1.05 74 IEEE Power Save PM1 DTIM3 (Avg.) d Rate 1 0.35 86 IEEE Power Save PM2 DTIM1 (Avg.) c Rate 1 1.05 74 IEEE Power Save PM2 DTIM3 (Avg.) d Rate 1 0.35 86 N/A 37 12 Rate 1 39 12 Rate 11 40 12 Rate 54 40 12 Rate MCS7 41 12 Sleep Modes Leakage (OFF) Sleep (idle, unassociated) a Sleep (idle, associated, inter-beacons) b Active Modes Rx Listen Mode e Rx Active (at –50dBm RSSI) f Tx f a. b. c. d. e. f. Rate 1 @ 20 dBm 320 15 Rate 11 @ 18 dBm 290 15 Rate 54 @ 15 dBm 260 15 Rate C7 @ 15 dBm 260 15 Device is initialized in Sleep mode, but not associated. Device is associated, and then enters Power Save mode (idle between beacons). Beacon interval = 100 ms; beacon duration = 1 ms @ 1 Mbps (Integrated Sleep + wakeup + beacon). Beacon interval = 300 ms; beacon duration = 1 ms @ 1 Mbps (Integrated Sleep + wakeup + beacon). Carrier sense (CCA) when no carrier present. Tx output power is measured on the chip-out side; duty cycle =100%. Tx Active mode is measured in Packet Engine mode (pseudo-random data) Document Number: 002-14781 Rev. *C Page 57 of 68 PRELIMINARY CYW43364 13. Interface Timing and AC Characteristics Note: Values in this data sheet are design goals and are subject to change based on the results of device characterization. Unless otherwise stated, the specifications in this section apply when the operating conditions are within the limits specified in Table 15 on page 44 and Table 17 on page 45. Functional operation outside of these limits is not guaranteed. 13.1 SDIO Default Mode Timing SDIO default mode timing is shown by the combination of Figure 24 and Table 27 on page 59. Figure 24. SDIO Bus Timing (Default Mode) fPP tWL tWH SDIO_CLK tTHL tTLH tISU tIH Input Output tODLY (max) Document Number: 002-14781 Rev. *C tODLY (min) Page 58 of 68 PRELIMINARY CYW43364 Table 27. SDIO Bus Timing a Parameters (Default Mode) Parameter Symbol Minimum Typical Maximum Unit 0 – 25 MHz b SDIO CLK (All values are referred to minimum VIH and maximum VIL ) Frequency—Data Transfer mode fPP Frequency—Identification mode fOD 0 – 400 kHz Clock low time tWL 10 – – ns Clock high time tWH 10 – – ns Clock rise time tTLH – – 10 ns Clock fall time tTHL – – 10 ns Input setup time tISU 5 – – ns Input hold time tIH 5 – – ns Output delay time—Data Transfer mode tODLY 0 – 14 ns Output delay time—Identification mode tODLY 0 – 50 ns Inputs: CMD, DAT (referenced to CLK) Outputs: CMD, DAT (referenced to CLK) a. b. Timing is based on CL 40 pF load on command and data. Min (Vih) = 0.7 × VDDIO and max (Vil) = 0.2 × VDDIO. 13.2 SDIO High-Speed Mode Timing SDIO high-speed mode timing is shown by the combination of Figure 25 and Table 28. Figure 25. SDIO Bus Timing (High-Speed Mode) fPP tWL tWH 50% VDD SDIO_CLK tTHL tISU tTLH tIH Input Output tODLY Document Number: 002-14781 Rev. *C tOH Page 59 of 68 PRELIMINARY CYW43364 Table 28. SDIO Bus Timing a Parameters (High-Speed Mode) Parameter Symbol Minimum Typical Maximum Unit b SDIO CLK (all values are referred to minimum VIH and maximum VIL ) Frequency – Data Transfer Mode fPP 0 – 50 MHz Frequency – Identification Mode fOD 0 – 400 kHz Clock low time tWL 7 – – ns Clock high time tWH 7 – – ns Clock rise time tTLH – – 3 ns Clock fall time tTHL – – 3 ns Input setup time tISU 6 – – ns Input hold time tIH 2 – – ns tODLY – – 14 ns Output hold time tOH 2.5 – – ns Total system capacitance (each line) CL – – 40 pF Inputs: CMD, DAT (referenced to CLK) Outputs: CMD, DAT (referenced to CLK) Output delay time – Data Transfer Mode a. b. Timing is based on CL 40 pF load on command and data. Min (Vih) = 0.7 × VDDIO and max (Vil) = 0.2 × VDDIO. 13.3 gSPI Signal Timing The gSPI device always samples data on the rising edge of the clock. Figure 26. gSPI Timing T1 T4 T2 T5 T3 SPI_CLK T6 T7 SPI_DIN T8 T9 SPI_DOUT (falling edge) Document Number: 002-14781 Rev. *C Page 60 of 68 PRELIMINARY CYW43364 Table 29. gSPI Timing Parameters Parameter Symbol Minimum Maximum Units T1 20.8 – ns Fmax = 50 MHz Clock high/low T2/T3 (0.45 × T1) – T4 (0.55 × T1) – T4 ns – Clock rise/fall time T4/T5 – 2.5 ns – Input setup time T6 5.0 – ns Setup time, SIMO valid to SPI_CLK active edge Input hold time T7 5.0 – ns Hold time, SPI_CLK active edge to SIMO invalid Output setup time T8 5.0 – ns Setup time, SOMI valid before SPI_CLK rising Output hold time T9 5.0 – ns Hold time, SPI_CLK active edge to SOMI invalid CSX to clocka – 7.86 – ns CSX fall to 1st rising edge Clock to CSXc – – – ns Last falling edge to CSX high Clock period a. Note SPI_CSx remains active for entire duration of gSPI read/write/write_read transaction (that is, overall words for multiple word transaction). 13.4 JTAG Timing Table 30. JTAG Timing Characteristics Period Output Maximum Output Minimum Setup Hold TCK 125 ns – – – – TDI – – – 20 ns 0 ns TMS – – – 20 ns 0 ns TDO – 100 ns 0 ns – – 250 ns – – – – Signal Name JTAG_TRST Document Number: 002-14781 Rev. *C Page 61 of 68 PRELIMINARY CYW43364 14. Power-Up Sequence and Timing 14.1 Sequencing of Reset and Regulator Control Signals The CYW43364 WL_REG_ON signal allows the host to control power consumption by enabling or disabling the WLAN and internal regulator blocks. These signals are described below. Additionally, diagrams are provided to indicate proper sequencing of the signals for various operational states (see Figure 27 and Figure 28). The timing values indicated are minimum required values; longer delays are also acceptable. Note: ■ The CYW43364 has an internal power-on reset (POR) circuit. The device will be held in reset for a maximum of 110 ms after VDDC and VDDIO have both passed the POR threshold (see Table 17 on page 45). Wait at least 150 ms after VDDC and VDDIO are available before initiating SDIO accesses. ■ VBAT and VDDIO should not rise faster than 40 µs. VBAT should be up before or at the same time as VDDIO. VDDIO should not be present first or be held high before VBAT is high. 14.1.1 Control Signal Timing Diagrams Figure 27. WLAN = ON 32.678 kHz Sleep Clock VBAT 90% of VH VDDIO ~ 2 Sleep cycles WL_REG_ON Figure 28. WLAN = OFF 32.678 kHz Sleep Clock VBAT VDDIO WL_REG_ON Document Number: 002-14781 Rev. *C Page 62 of 68 PRELIMINARY CYW43364 15. Package Information 15.1 Package Thermal Characteristics Table 31. Package Thermal Characteristicsa Characteristic Value in Still Air JA (°C/W) JB (°C/W) JC (°C/W) 13.14 JT (°C/W) 0.04 JB (°C/W) 14.21 53.11 6.36 Maximum Junction Temperature Tj (°C)b 125 Maximum Power Dissipation (W) 1.2 a. b. No heat sink, TA = 70°C. This is an estimate based on a 4-layer PCB that conforms to EIA/JESD51–7 (101.6 mm x 114.3 mm x 1.6 mm) and P = 1.2W continuous dissipation. Absolute junction temperature limits maintained through active thermal monitoring and dynamic TX duty cycle limiting. 15.1.1 Junction Temperature Estimation and PSI Versus Thetajc Package thermal characterization parameter PSI-JT (JT) yields a better estimation of actual junction temperature (TJ) versus using the junction-to-case thermal resistance parameter Theta-JC (JC). The reason for this is JC assumes that all the power is dissipated through the top surface of the package case. In actual applications, some of the power is dissipated through the bottom and sides of the package. JT takes into account power dissipated through the top, bottom, and sides of the package. The equation for calculating the device junction temperature is as follows: TJ = TT + P JT Where: ■ TJ = junction temperature at steady-state condition, °C ■ TT = package case top center temperature at steady-state condition, °C ■ P = device power dissipation, Watts ■ JT = package thermal characteristics (no airflow), °C/W Document Number: 002-14781 Rev. *C Page 63 of 68 PRELIMINARY CYW43364 16. Mechanical Information Figure 29 shows the mechanical drawing for the CYW43364 WLBGA package. Figure 29. 74-Ball WLBGA Mechanical Information Document Number: 002-14781 Rev. *C Page 64 of 68 PRELIMINARY CYW43364 Figure 30. WLBGA Package Keep-Out Areas—Top View with the Bumps Facing Down Document Number: 002-14781 Rev. *C Page 65 of 68 PRELIMINARY CYW43364 17. Ordering Information Part Number a CYW43364KUBG Package 74-ball WLBGA halogen-free package (4.87 mm x 2.87 mm, 0.40 pitch) Description 2.4 GHz single-band WLAN IEEE 802.11n Operating Ambient Temperature –30°C to +70°C a. Add a “T” to the end of the part number to specify “Tape and Reel.” Document Number: 002-14781 Rev. *C Page 66 of 68 PRELIMINARY CYW43364 Document History Document Title: CYW43364 Single-Chip IEEE 802.11 b/g/n MAC/Baseband/Radio Document Number: 002-14781 Revision ECN Orig. of Change Submission Date ** – – 12/08/14 Description of Change 43364-DS100-R Initial release 43364-DS101-R Updated: ■ Figure 3: “Typical Power Topology (1 of 2),” on page 14. ■ Figure 4: “Typical Power Topology (2 of 2),” on page 15. ■ Figure 22: “74-Ball WLBGA Ball Map (Bottom View),” on page 44. *A – – 08/06/15 ■ Table 7: “BCM43364 WLBGA Ball List — Ordered By Ball Number,” on page 45. ■ Table 8: “BCM43364 WLBGA Ball List — Ordered By Ball Name,” on page 48. ■ Table 9: “WLBGA Signal Descriptions,” on page 49. ■ Table 12: “I/O States,” on page 53. ■ Table 18: “WLAN 2.4 GHz Receiver Performance Specifications,” on page 59. ■ Table 19: “WLAN 2.4 GHz Transmitter Performance Specifications,” on page 62. ■ Table 25: “2.4 GHz Mode WLAN Power Consumption,” on page 70. *B – – 10/05/15 *C 5525641 UTSV 11/18/16 43364-DS102-R Updated: ■ Table 10, “WLBGA Signal Descriptions,” on page 38 ■ Table 13, “I/O States,” on page 42 Document Number: 002-14781 Rev. *C Updated to Cypress format Page 67 of 68 PRELIMINARY CYW43364 Sales, Solutions, and Legal Information Worldwide Sales and Design Support Cypress maintains a worldwide network of offices, solution centers, manufacturer’s representatives, and distributors. To find the office closest to you, visit us at Cypress Locations. PSoC®Solutions Products ARM® Cortex® Microcontrollers Automotive cypress.com/arm cypress.com/automotive Clocks & Buffers Interface cypress.com/clocks cypress.com/interface Internet of Things Lighting & Power Control Memory cypress.com/iot cypress.com/powerpsoc cypress.com/memory PSoC Cypress Developer Community Forums | WICED IoT Forums | Projects | Video | Blogs | Training | Components Technical Support cypress.com/support cypress.com/psoc Touch Sensing cypress.com/touch USB Controllers Wireless/RF PSoC 1 | PSoC 3 | PSoC 4 | PSoC 5LP cypress.com/usb cypress.com/wireless 68 © Cypress Semiconductor Corporation, 2014-2016. This document is the property of Cypress Semiconductor Corporation and its subsidiaries, including Spansion LLC (“Cypress”). This document, including any software or firmware included or referenced in this document (“Software”), is owned by Cypress under the intellectual property laws and treaties of the United States and other countries worldwide. Cypress reserves all rights under such laws and treaties and does not, except as specifically stated in this paragraph, grant any license under its patents, copyrights, trademarks, or other intellectual property rights. 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You shall indemnify and hold Cypress harmless from and against all claims, costs, damages, and other liabilities, including claims for personal injury or death, arising from or related to any Unintended Uses of Cypress products. Cypress, the Cypress logo, Spansion, the Spansion logo, and combinations thereof, WICED, PSoC, CapSense, EZ-USB, F-RAM, and Traveo are trademarks or registered trademarks of Cypress in the United States and other countries. For a more complete list of Cypress trademarks, visit cypress.com. Other names and brands may be claimed as property of their respective owners. Document Number: 002-14781 Rev. *C Revised November 18, 2016 Page 68 of 68