RFMD SIW3500DIF1

SiW3500
Preliminary
• Bluetooth specification V1.2 qualified
including mandatory and optional
functions such as AFH and eSCO.
PLL
Control
ADDRESS BUS
VDD_P
VBB_OUT
VCC_OUT
VBATT_DIG
VBATT_ANA
XTAL_N
CLK_REQ_IN
XTAL_P/CLK
CLK_REQ_OUT
VTUNE
• RF System on Chip (SoC) for
Bluetooth wireless technology
combining a 2.4 GHz transceiver,
baseband processor, and protocol
stack ROM.
CHG_PUMP
Features
Voltage Regulators and
Power Distribution
Clock Distribution
CS, OE and WE
0
DATA BUS
ULTIMATEBLUE
Optional flash interface
LNA
ADC
• Manufactured using standard
0.18-micron CMOS process
technology.
ARM7TDMI®
Processor
UART
Data SRAM
Multi Function
I/Os
Firmware ROM
Audio CODEC
Interface
0
90
• UART based Host Control Interface
(HCI) transport layer supports
standard and 3-wire modes.
RF_I/O
Internal
50-Ohm
Match
Network
ADC
PLL
Synthesizer
GFSK
Modem
Bluetooth
Link
Controller
DAC
Power
Control
0
• Direct conversion RF architecture
improves receiver-blocking
performance.
90
DRIVER
DAC
Aux ADC
• I/O voltage supply can range from
1.62 V to 3.63 V.
Block Diagram
• -85 dBm receiver sensitivity and
+2 dBm transmitter power typical
performance specifications.
• Integrated analog and digital voltage
regulators simplify system design.
• 50 Ω RF I/O does not need any
additional external impedance
matching components.
Product Description
The UltimateBlue SiW3500™ is a RF System On Chip (SoC) that combines
a 2.4 GHz transceiver, baseband processor, and protocol stack software for
Bluetooth® wireless technology. Due to its low power CMOS process, the
SiW3500 is ideally suited for applications such as mobile phones, audio
• Flexible reference clock source
options including crystal or direct
input from the host platform.
headsets, and other embedded products.
• Internal temperature compensated
transmitter and receiver circuits
deliver consistent performance from
-40° to +85°C.
The SiW3500 integrates an ARM7TDMI processor for software execution
• On-chip ROM software storage with
patch capability.
the HCI transport driver.
Applications
from either internal ROM or external FLASH memory. The standard
SiW3500 ROM contains the Bluetooth lower layer stack software including
The SiW3500 is packaged in a 6 x 6 Pb-Free 96-VFBGA that meets RoHS
(Green) requirements. Known Good Die (KGD) is available for special
applications.
• Mobile phones and smart phones.
• Bluetooth audio headset.
• Bluetooth hands-free kit.
Ordering Information
SiW3500
UltimateBlue
Optimum Technology Matching® Applied
Si BJT
GaAs HBT
Si Bi-CMOS
SiGe HBT
GaInP/HBT
GaN HEMT
9
GaAs MESFET
Si CMOS
SiGe Bi-CMOS
RF Micro Devices, Inc.
7628 Thorndike Road
Greensboro, NC 27409, USA
Tel (336) 664 1233
Fax (336) 664 0454
http://www.rfmd.com
60 0066 R00Hrf SiW3500 Radio Processor DS
November 8, 2004
14-37
SiW3500
Preliminary
Radio Features
•
RF System on Chip (SoC) for Bluetooth wireless technology combining a 2.4 GHz transceiver, baseband processor,
and protocol stack ROM.
•
Bluetooth specification V1.2 qualified including mandatory and optional functions such as AFH and eSCO.
•
Manufactured using standard 0.18 m CMOS process technology.
•
UART based Host Control Interface (HCI) transport layer supports standard and 3-wire modes.
•
Direct conversion RF architecture improves receiver-blocking performance.
•
I/O voltage supply can range from 1.62 V to 3.63 V.
• -85 dBm receiver sensitivity and +2 dBm transmitter power typical performance specifications.
•
Integrated analog and digital voltage regulators simplify system design.
•
50 Ω RF I/O does not need any additional external impedance matching components.
•
Flexible reference clock source options including crystal or direct input from the host platform.
•
Internal temperature compensated transmitter and receiver circuits deliver consistent performance from -40° to
+85°C.
•
On-chip ROM software storage with patch capability.
Baseband Features
•
Hardware based GFSK MODEM and packet processing contributes to lower system current consumption with
minimal software overhead.
•
ARM7TDMI processor efficiently executes all protocol stack and application software.
•
Software execution from either internal ROM or external FLASH memory. The SiW3500 features a ROM patch
mechanism that allows substituting small portions of ROM code with code either downloaded from the host or stored
in external EEPROM.
•
Extensive multi function I/Os allow flexible product configurations.
•
Auxiliary analog-to-digital converter (ADC) is available for applications such as battery level detection.
Standard Protocol Stack Features
•
Full-featured lower layer Bluetooth protocol stack software up to the host interface (HCI).
• Bluetooth 1.2 qualified including mandatory and optional features such as AFH, extended SCO, faster connections,
and LMP improvements.
• Full Bluetooth connection capabilities with support for piconet and scatternet modes and device scanning during SCO
connection.
• Able to establish up to 3 SCO connections simultaneously.
•
Supports low power connection states such as hold, sniff, and park modes with selectable sniff intervals.
•
Full support of Bluetooth test modes for use during production.
•
Verified HCI command level compatibility with multiple upper layer stack software.
Additional Protocol Stack Features
• Proprietary channel assessment algorithm provides fast and accurate determination of occupied channel for use in
AFH mode.
•
In addition to AFH, UltimateBlue Coexistence Technology is part of the baseline protocol stack. UltimateBlue
coexistence minimizes interference to 802.11b/g products.
• The Channel Quality Driven Data Rate (CQDDR) feature optimizes data transfer in noisy or weak signal
environments.
• Full selection of upper layer protocol stack software and profiles available for license and customization.
14-38
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
SiW3500
SiW3500
HCI
Headset
Lower stack up to HCI
[
[
UltimateBlue Coexistence
[
[
Upper Stack (L2CAP, SDP, RFCOMM)
–
Programming Interface (API)
–
[
[
Headset Profile (HSP)
–
[
Hands Free Profile (HFP)
–
[
ROM Features
Protocol Stack
Profiles
[ = Included in SiW3500 ROM
External System Interfaces
Host HCI Transport (UART)
The high speed UART interface provides the physical transport between the SiW3500 and the application host for the
transfer of Bluetooth data compliant with the Bluetooth specification. The table below shows the supported configurations. The default baud rate is 115,200 bps and can be set depending on the product.
SiW3500 Radio Processor HCI UART Parameters
Number of data bits
Required Host Setting
8
Parity bit
No parity
Stop bit
1 stop bit
Flow control
RTS/CTS
Host flow-off response requirement from the SiW3500
8 bytes
SiW3500 IC flow-off response requirement from host
2 bytes
Supported baud rates
9.6k, 19.2k, 38.4k, 57.6k, 115.2k, 230.4k, 460.8k, 500k, 921.6k,
1M, 1.5M, 2M
Host HCI Transport (3-Wire UART)
To reduce the number of signals and to increase the reliability of the HCI UART interface, a 3-wire UART protocol is
available in the SiW3500. The protocol is compliant with the Bluetooth specification H:5 transport and backwards
compatible with the BCSP 3-wire UART protocol. Selection between H:4 UART, H:5 UART, and BCSP UART is done
automatically by the SiW3500.
SiW3500 Radio Processor HCI 3-Wire UART Parameters
Required Host Setting
Number of data bits
8
Parity bit
Even
Stop bit
1 stop bit
Error detection
SLIP and checksum
Sleep modes
Shallow and deep
Audio Codec Interface
The SiW3500 supports direct interface to an external audio CODEC or PCM host device. The interface provides the
following configurations:
•
•
•
•
Standard PCM clock rates from 64 kHz to 2.048 MHz with multi-slot handshakes and synchronization.
Supports either master or slave mode.
Supports any PCM data size up to 16 bits.
Compatible with Motorola SSI mode.
60 0066 R00Hrf SiW3500 Radio Processor DS
14-39
SiW3500
Preliminary
•
Configuration of the CODEC interface is done by the firmware during boot-up by reading non-volatile memory (NVM)
parameters.
Multi-function I/Os (MFPs)
Up to 8 (eight) multi-function I/O ports are available in the SiW3500. The table below identifies the I/Os and their usage.
Multi Function I/O Number
Possible Usage Configuration
MFP[0]
General purpose.
MFP[1]
CLOCK_REQ_IN, HOST_WAKEUP, General purpose.
MFP[2]
Address A[18], SYNC_CLOCK, AUX_RTS, General purpose.
MFP[3]
FREQ_SEL[3], SYNC_DATA, General purpose.
MFP[4]
FREQ_SEL[1], General purpose.
MFP[5]
FREQ_SEL[2], General purpose.
MFP[6]
AUX_RXD, General purpose.
MFP[7]
AUX_CTS, TX_RX_SWITCH, General purpose.
External Memory Interface
The SiW3500 does not require additional memory for standard below HCI protocol functions. An external memory
interface is available for execution of protocol stack software from FLASH memory if desired. If external FLASH memory
will be used, the read access time of the device must be 100 ns or less.
Auxiliary UART
The SiW3500 can be configured and enabled with an auxiliary UART port. This UART port can be used for debug
depending on the application software.
Signal
AUX_TXD
Description
TX Data
AUX_RXD
RX Data
AUX_CTS
Clear To Send
AUX_RTS
Request To Send
External Power Amplifier Interface
The SiW3500 supports the use of an external power amplifier for +20 dBm designs. When enabled, these signals
provide an integrated interface for the control of an external PA.
Signal
Description
IDAC
Power control to external PA. This output provides a variable current source
that can be used to control the external PA. Leave unconnected if not used
TX_RX_SWITCH
Output signal used to indicate the state of the radio. This could be used as a
direction control for the PA. The polarity is programmable with the default set
as: Low = Transmit; High = Receive.
Power Management
The HOST_WAKEUP and EXT_WAKE signals are used for power management control of the SiW3500.
HOST_WAKEUP is an output signal used to indicate Bluetooth activity to the host. EXT_WAKE is an input signal used
by the host to wake up the SiW3500 from sleep mode.
For control of the reference clock source, CLOCK_REQ_IN and CLOCK_REQ_OUT can be made available to turn on/off
an external reference clock source.
General-Purpose Analog to Digital Converter (ADC)
The SiW3500 incorporates a general-purpose ADC that can be enabled to sample external analog voltage. The ADC
has an 8-bit resolution.
External EEPROM Controller and Interface
This interface is intended for communication to an optional EEPROM when using the SiW3500 in ROM mode. The
14-40
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
EEPROM is not required for configurations with external flash. The EEPROM is the non-volatile memory (NVM) in the
system and contains the system configuration parameters such as the Bluetooth device address, the CODEC type, as
well as other parameters. These default parameters are set at the factory, and some parameters will change depending
on the system configuration. Optionally, the memory parameters can be downloaded from the host processor at boot up
eliminating the need for EEPROM. Please consult the Application Support team for details. The EEPROMs should have
a serial I2C interface with a minimum size of 2 Kbits and 16-byte page write buffer capabilities.
General System Requirements
System Reference Clock
The SiW3500 chip can use either an external crystal or a reference clock as the system clock input. A partial list of
supported frequencies (in MHz) includes: 9.6, 12, 12.8, 13, 14.4, 15.36, 16, 16.8, 19.2, 19.68, 19.8, 26, 32, 38.4, and 48.
For other frequencies, please contact Applications Support. The system reference crystal/clock must have an accuracy
of ±20 PPM or better to meet the Bluetooth specification.
Low Power Clock
For the Bluetooth low power clock, a 32.768 kHz crystal can be used to drive the SiW3500 oscillator circuit, or alternatively, a 32.768 kHz reference clock signal can be used instead of a crystal. If the lowest power consumption is not
required during low-power modes such as sniff, hold, park, and idle modes, the 32.768 kHz crystal may be omitted in the
design.
If the 32.768 kHz clock source is used, the clock source should be connected to the CLK32_IN pin and must meet the
following requirements:
•
For AC-coupled via 100 pF or greater (peak-to-peak voltage):
400 mVP-P < CLK32_IN < VDD_C
•
For DC-coupled:
CLK32_IN minimum peak voltage < VIL
CLK32_IN maximum peak voltage > VIH
Where VIL = 0.3 * VDD_C
Where VIH = 0.7 * VDD_C
•
For both cases, the signal is not to exceed:
-0.3 V < CLK32_IN < VDD_C + 0.3 V
Power Supply Description
The SiW3500 operates at 1.8 V core voltage for internal analog and digital circuits. The chip has internal analog and
digital voltage regulators simplifying power supply requirements to the chip. The internal voltage regulators can be
supplied directly from a battery or from other system voltage sources. Optionally, the internal regulators can be bypassed if 1.8 V regulated source is available on the system.
Function
Internal Analog Regulator
Internal Digital Regulator
VBATT_ANA = 2.3 to 3.63 V
VBATT_DIG = 2.3 to 3.63 V
VCC_OUT = 1.8 V
VDD_C = 1.8 V
Function
Analog Core Circuits
Digital Core Circuits
Circuit voltage supply pin
VCC = 1.8 V
VDD_C = 1.8 V
Regulator input pin
Regulator output pin
Internal Regulator Used
Internal Regulator Bypassed
Note: Both regulators can be bypassed if external regulation is desired. When bypassing the analog regulator, the VBATT_ANA and VCC_OUT pins
must be tied together and the external analog voltage (1.8 V) should be applied to the VBATT_ANA pin. When bypassing the digital regulator, the
VBATT_DIG pin should be left unconnected and the external digital voltage (1.8 V) should be applied to VBB_OUT pin.
The power for the I/Os is taken from two separate sources (VDD_P and VDD_P_ALT). They can range from 1.62 to 3.63
60 0066 R00Hrf SiW3500 Radio Processor DS
14-41
SiW3500
Preliminary
Volts to maintain compatibility with a wide range of peripheral devices. Please check the pin list for the exact pins that are
powered from the VDD_P and VDD_P_ALT sources.
RF I/O Description
The SiW3500 employs single-ended RF input and output pins for reduced external components. In typical Class 2 (0
dBm nominal) applications, no external matching components are necessary.
On-Chip Memory
The SiW3500 Radio Processor integrates both SRAM and ROM. The ROM is pre-programmed with Bluetooth protocol
stack software (HCI software) and boot code that executes automatically upon reset. The boot code serves to control the
boot sequence as well as to direct the execution to the appropriate memory for continued operation.
Configuration Selection
Reference Frequency Selection
The SiW3500 is designed to operate with multiple reference frequencies. During boot, specific frequency select I/O pins
are sampled to determine the default reference frequency. The reference frequency setting will be set according to the
following table:
FREQ_SEL3
(MFP[3])
FREQ_SEL2
(MFP[5])
FREQ_SEL1
(MFP[4])
FREQ_SEL0
(ADC_IN)
Frequency
0
0
0
0
0
0
0
1
15.36 MHz
19.2 MHz
0
0
1
0
19.44 MHz
0
0
1
1
19.68 MHz
0
1
0
0
19.8 MHz
0
1
0
1
26 MHz
0
1
1
0
38.4 MHz
0
1
1
1
Do not program frequency (leave as ref/2 and set
according to system parameters).
1
0
X
X
32 MHz
1
1
0
0
32 MHz
1
1
0
1
12 MHz
1
1
1
0
13 MHz
1
1
1
1
14.4 MHz
Application Software Memory Selection
The SiW3500 can support application (protocol stack) software execution from internal ROM or external FLASH
memory. To run from internal ROM, pins D[9] and D[10] must be connected together as shown in the application circuit
section of this document (Application Circuit). To run from external flash memory, the flash must be connected as shown
in the application circuit diagram and contain valid application code. If the external memory does not have valid program
data, the device enters a download mode in which a valid program may be loaded into the external memory through a
sequence of commands over the HCI transport layer.
14-42
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
Pin Description
The following table provides detailed listings of pin descriptions arranged by functional groupings.
Name
Pad Type
Ball
Description
Radio (Power from VCC)
RF_IO
Analog
A2
RF signal. Input and output.
TX_BIAS
Analog
A4
Internal transmitter driver bias.
VTUNE
Analog
A6
Pin for reference PLL loop filter, only used if reference frequency is not
integer multiples of 4 MHz.
CHG_PUMP
Analog
F1
Pin for RF loop filter.
XTAL_N
Analog
B7
System clock crystal negative input. If a reference clock is used, this pin
should be left unconnected.
XTAL_P/CLK
Analog
A7
System clock crystal positive input or reference clock input.
IDAC
Analog
B1
Power control to external power amplifier. This output provides a variable
current source that can be used to control the external power amp. Leave
unconnected if not used.
ADC_IN
Analog
J2
Analog to digital converter input or FREQ_SEL_(0).
VREFN_CAP
Analog
C2
Decoupling capacitor for internal A/D converter voltage reference.
VREFP_CAP
Analog
C1
Decoupling capacitor for internal A/D converter voltage reference.
Low Power Oscillator and Reset (Power from VDD_P_ALT)
CLK32K_IN
Analog
L1
For crystal or external clock input (32.768 kHz).
CLK32K_OUT
Analog
K1
Drive for crystal.
RESET_N
CMOS input
G1
System level reset (active low).
Power Control Interface (Power from VDD_P)
PWR_REG_EN
CMOS bi-directional
G2
CLOCK_REQ_OUT control line for external TCXO by default, or can be
used as enable for an external voltage regulator. Programmable active
high or active low.
AUX_TXD
CMOS bi-directional
G9
Auxiliary UART serial port output.
Multi-function (MFP) I/O (Power from VDD_P)
MFP [0]
CMOS bi-directional
F3
Multi-function I/O port.
MFP [1]
CMOS bi-directional
J1
Multi-function I/O port.
MFP [2]
CMOS bi-directional
L6
Multi-function I/O port.
MFP [3]
CMOS bi-directional
F10
Multi-function I/O port.
MFP [4]
CMOS bi-directional
B9
Multi-function I/O port.
MFP [5]
CMOS bi-directional
C8
Multi-function I/O port.
MFP [6]
CMOS bi-directional
C7
Multi-function I/O port.
MFP [7]
CMOS bi-directional
C6
Multi-function I/O port.
PCM data output from SiW3500.
PCM Interface (Power from VDD_P_ALT)
PCM_IN
CMOS bi-directional
H3
PCM_OUT
CMOS bi-directional
L2
PCM data input to SiW3500.
PCM_CLK
CMOS bi-directional
K3
PCM synchronous data clock to the remote device. Normally an output.
Input for slave mode.
PCM_SYNC
CMOS bi-directional
K2
PCM synchronization data strobe to the remote device. Normally an output. Input for slave mode.
Table 1. SiW3500 Radio Processor Pin List
60 0066 R00Hrf SiW3500 Radio Processor DS
14-43
SiW3500
Name
Preliminary
Pad Type
Ball
Description
UART Interface (Power from VDD_P_ALT)
UART_RXD
CMOS input
G3
UART receive data.
UART_TXD
CMOS output
L4
UART transmit data.
UART_CTS
CMOS input
H2
UART flow control clear to send.
UART_RTS
CMOS output
H1
UART flow control ready to send.
EXT_WAKE
CMOS input
C5
Wake up signal from host.
External Memory Interface (power from VDD_P)
A[17]
A[16]
A[15]
A[14]
A[13]
A[12]
A[11]
A[10]
A[9]
A[8]
A[7]
A[6]
A[5]
A[4]
A[3]
A[2]
A[1]
CMOS output
E11
J11
L5
F11
B8
K6
L7
A10
H11
A11
B11
K9
K7
C10
K10
D10
L11
D[15]
D[14]
D[13]
D[12]
D[11]
D[10]
D[9]
D[8]
D[7]
D[6]
D[5]
D[4]
D[3]
D[2]
D[1]
D[0]
CMOS bi-directional
A9
C9
B10
E10
K5
G11
G10
H9
K4
J9
K8
J6
J5
F9
J4
H10
OE_N
CMOS output
L10
Address lines.
Note: A[17] and A[16] can be used to support an optional external serial
EEPROM when using the internal ROM in place of the external Flash
memory.
Data lines.
Note: Connect D[9] to D[10] to use internal ROM.
Output enable for external memory (active low).
WE_N/EEPROM_WP
CMOS output
A8
Write enable for external memory (active low).
FCS_N
CMOS output
J10
Chip select for external memory (active low).
VBATT_ANA
Power
D3
Positive supply to internal analog voltage regulator.
VBATT_DIG
Power
L9
Positive supply to internal digital voltage regulator.
VCC_OUT
Power
D1
Regulated output from internal analog voltage regulator.
VDD_P
Power
D11
K11
Positive supply for external memory interface and some digital I/Os.
VDD_C
Power
C11
L8
Positive supply for digital circuitry or output of internal digital voltage.
Power and Ground
Table 1. SiW3500 Radio Processor Pin List (Continued)
14-44
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
Name
Pad Type
Ball
VCC
Power
A1
B6
C4
E1
E3
VSS_P
GND
J8
E9
Description
Positive supply for RF and analog circuitry.
Ground connections for VDD_P.
VDD_P_ALT
Power
L3
Positive supply for UART, CODEC, and other digital I/Os.
VSS_P_ALT
Ground
J3
Ground connection for VDD_P_ALT.
GND
A3
A5
B2
B3
B4
B5
C3
D2
E2
F2
D9
J7
Ground connections for RF and analog circuitry.
GND
Table 1. SiW3500 Radio Processor Pin List (Continued)
60 0066 R00Hrf SiW3500 Radio Processor DS
14-45
SiW3500
Preliminary
System Specifications
Absolute Maximum Ratings
Parameter
VDD_C
VCC
VDD_P, VDD_P_ALT
VBATT_ANA
VBATT_DIG
TST
RFMAX
Description
Digital circuit supply voltage
Analog circuit supply voltage
I/O supply voltage
Analog regulator supply voltage
Digital regulator supply voltage
Storage temperature
Maximum RF input level
Min
Max
Unit
-0.3
-0.3
-0.3
-0.3
-0.3
-55
–
3.63
3.63
3.63
3.63
3.63
+125
+5
V
V
V
V
V
°C
dBm
Note: Absolute maximum ratings indicate limits beyond which the useful life of the device may be impaired or damage may occur.
Recommended Operating Conditions
Parameter
TOP
TEOP
VBATT_ANA
VBATT_DIG
VCC
VDD_C
VDD_P , VDD_P_ALT
Description
Operating temperature (industrial grade)
Extended operating temperature1
Unregulated supply voltage into internal analog regulator
Unregulated supply voltage into internal digital regulator
Regulated supply voltage directly into analog circuits
Regulated supply voltage directly into digital circuits
Digital interface I/O supply voltage
Min
Max
Unit
-40
-40
2.3
2.3
1.71
1.62
1.62
+85
+105
3.63
3.63
1.89
1.98
3.63
°C
°C
V
V
V
V
V
1.The extended operating temperature range applies to special order devices qualified for extended operating range. Please contact factory for details.
ESD Rating
Symbol
ESD
Description
Rating
ESD protection - all pins
2000 V
Note: This device is a high performance RF integrated circuit with an ESD rating of 2,000 volts (HBM conditions per Mil-Std-883, Method 3015).
Handling and assembly of this device should only be done using appropriate ESD controlled processes.
Electrical Characteristics
DC Specification (TOP =+25°C, VDD_P =3.0V)
Symbol
Description
Min.
Typ
Max.
.V
Unit
VIL
Input low voltage
GND-0.1
–
VIH
Input high voltage
0.7. VDD_P
–
VDD_P
V
VOL
Output low voltage
GND
–
0.2 . VDD_P
V
–
VDD_P
V
1
1
1
–
–
–
mA
mA
µA
Typ
Max.
Unit
5
5
11
8
ns
ns
VOH
Output high voltage
IOH
IOL
IILI
Output high current
Output low current
Input leakage current
AC Characteristics (TOP =+25°C, VDD_P =3.0V, CLOAD =15pF)
Symbol
Description
tr
tf
14-46
Rise time
Fall time
0.8
.V
DD_P
–
–
–
0.3
DD_P
V
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
Current Consumption (TOP =+25°C, VBATT =3.0V using internal regulators)
Operating Mode
Average
Max
Unit
Continuous transmit*
40
48
80
55
µA
mA
Continuous receive*
Parked slave, 1.28 sec. interval
Inquiry scan, 1.28 sec interval
Page scan, 1.28 sec. interval
ACL connection, sniff mode, 40 ms interval
ACL data transfer 723 kbps TX, 57 kbps RX
SCO connection, HV3 packets
54
90
440
560
1.3
42
22
60
–
–
–
–
–
–
mA
µA
µA
µA
mA
mA
mA
Standby
*Note: Continuous transmit and receive currents are measured in operating modes where there is no activity in baseband digital circuits.
Digital Regulator Specification (TOP = 25°C)
Parameter
Description
Min
Typ
Max
Unit
1.62
1.80
1.98
V
Output voltage
(I OUT = 10 mA)
Line regulation
(I OUT = 0 mA, VBATT_DIG = 2.3 V to 3.63 V)
–
8.0
–
mV
Load regulation
(I OUT = 3 mA to 80 mA)
–
9.0
–
mV
Dropout voltage
(I OUT = 10 mA)
–
–
250
mV
Output maximum
current
Maximum supplied current while maintaining regulation
–
–
80
mA
Quiescent current
Off current
–
10
–
µA
Ripple rejection
f RIPPLE = 400 Hz
–
40
–
dB
Min
Typ
Max
Unit
2402
–
2480
MHz
–
60
100
µs
Radio Specification
Parameter
VCO Operating
Range
PLL lock time
Description
Frequency
Average tune time
Receiver Specification1 (VBATT =3.3V, VCC =internal analog regulator output, TOP = 25°C)
Min
Typ
Max
Unit
Receiver sensitivity
Parameter
BER < 0.1%
–
-85
-78
dBm
Maximum
usable signal
BER < 0.1%
-10
0
–
dBm
C/I co-channel
(0.1% BER)
Co-channel selectivity
–
+8.0
+10.0
dB
C/I 1 MHz
(0.1% BER)
Adjacent channel selectivity
–
-4.0
-3.0
dB
C/I 2 MHz
(0.1% BER)
2nd adjacent channel selectivity
–
-38.0
-35.0
dB
C/I ≥ 3 MHz
(0.1% BER)
3rd adjacent channel selectivity
–
-43.0
-40.0
dB
Fc/3
-23
–
–
dBm
Fc/2
-25
–
–
dBm
2 * Fc/3
-45
–
–
dBm
Out-of-band
blocking2
Description
30 MHz - 2000 MHz
-10
–
–
dBm
2000 MHz - 2399 MHz
-27
–
–
dBm
2498 MHz - 3000 MHz
-27
–
–
dBm
3000 MHz - 12.75 GHz
-10
–
–
dBm
60 0066 R00Hrf SiW3500 Radio Processor DS
14-47
SiW3500
Preliminary
Parameter
Intermodulation
Receiver spurious
emission
Description
Min
Typ
Max
Unit
-39
-36
–
dBm
30 MHz to 1 GHz
–
–
-57
dBm
1 GHz to 12.75 GHz
–
–
-47
dBm
Max interferer level to maintain 0.1% BER, interference signals at 3 and 6 MHz offset.
1. Measured into the chip with 50 Ω source and no bandpass filter.
2. Out-of-band blocking guaranteed by design.
Transmitter Specification1 (VBATT =3.3V, VCC =internal analog regulator output, TOP = 25°C)
Parameter
Min
Typ
Max
Unit
-2
+2
+5
dBm
f1avg
140
155
175
kHz
f2max (For at least 99.9% of all f2max)
115
–
–
kHz
f1avg/ f2avg
0.8
–
–
kHz
–
-75
–
+75
kHz
One slot packet
-25
–
+25
kHz
Two slot packet
-40
–
+40
kHz
Five slot packet
-40
–
+40
kHz
Max drift rate
–
–
20
kHz/50 µs
20 dB occupied
bandwidth
Test per Bluetooth specification
–
–
1000
kHz
In-band spurious
emission
2 MHz offset
–
–
-40
dBm
>3 MHz offset
–
–
-60
dBm
30 MHz to 1 GHz, operating mode
–
–
-55
dBm
30 MHz to 1 GHz, idle mode
–
–
-57
dBm
1 GHz to 12.75 GHz, operating mode
–
–
-50
dBm
Output RF transmit
power
Description
At maximum power output level
Modulation
Characteristics2
Initial carrier
frequency accuracy
Carrier frequency
drift
Out-of-band
spurious
emission
1 GHz to 12.75 GHz, idle mode
–
–
-47
dBm
1.8 GHz to 1.9 GHz
–
–
-62
dBm
5.15 GHz to 5.3 GHz
–
–
-47
dBm
1. Measured into the chip with 50 Ω source and no bandpass filter.
2. Modulation characteristics as measured per test TRM/CA/07/C as defined in the Bluetooth test specification.
Industrial Temperature Performance1 (VBATT=2.3 – 3.63V, VCC =internal analog regulator output,
TOP = -40 to +85°C)
Parameter
Receiver
sensitivity
Output RF transmit power
Description
BER<0.1%
At maximum power output level
f1avg
Modulation
Characteristics2
f2max (For at least 99.9% of all f2max)
f1avg/ f2avg
Initial carrier frequency
accuracy
Carrier frequency drift
20 dB occupied bandwidth
In-band spurious emission
14-48
Min
Typ
Max
Unit
–
-85
-75
dBm
-4
+2
+6
dBm
140
155
175
kHz
115
–
–
kHz
–
–
kHz
0.8
–
-75
–
+75
kHz
One slot packet
Two slot packet
Five slot packet
Max drift rate
Bluetooth specification
2 MHz offset
>3 MHz offset
-25
-40
-40
–
–
–
–
–
–
–
–
–
–
–
+25
+40
+40
20
1000
-40
-60
kHz
kHz
kHz
kHz/50 µs
kHz
dBm
dBm
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
Parameter
Description
Out-of-band
spurious
emission
Min
Typ
Max
Unit
30 MHz to 1GHz, operating mode
–
–
-55
dBm
30 MHz to 1GHz, idle mode
–
–
-57
dBm
1 GHz to 12.75 GHz, operating mode
1 GHz to 12.75 GHz, idle mode
–
–
-70
–
-50
-47
dBm
dBm
1.8 GHz to 1.9 GHz
–
–
-62
dBm
5.15 GHz to 5.3 GHz
–
–
-47
dBm
1. Measured into the chip with 50 Ω impedance and no bandpass filter. Industrial temperature performance guaranteed by design.
2. The modulation characteristic is measured as per test TRM/CA/07/C defined in the Bluetooth Test Specification.
Analog Voltage Supply Requirements
The SiW3500 processor is designed for use with its own internal low noise analog voltage regulator. This configuration is
recommended for all applications. When necessary, the internal analog regulator can be bypassed. In situations where
bypassing the internal analog regulator is required, the supply voltage to the analog circuit must satisfy the following
requirements to preserve the RF performance characteristics.
Parameter
Description
Min
Max
Unit
VCC
Analog supply voltage to all VCC input pins
1.71
1.89
V
Minimum
load current
External regulator current
80
–
mA
Minimum
ripple rejection
At 400Hz
40
–
dB
Output noise
Integrated 10 Hz to 80 kHz noise
–
22
mV RMS
External Reference Requirements
It is possible to provide a number of reference frequencies that are typical in most cellular phones directly into ball B7
(XTAL_P/CLK) of the device. Refer to “System Reference Clock” on page 41 for a list of supported reference
frequencies.
Parameter
Description
100 Hz offset
Phase noise
Drive level
Min
Max
Unit
–
-100
dBc/Hz
1 kHz offset
–
-120
dBc/Hz
10 kHz offset
–
-140
dBc/Hz
AC amplitude
0.5
VCC
VP-P
DC levela
0.3
VCC
V
a.If DC-coupled, the external reference signal voltage must stay within this range at all times.
Reference Crystal Requirements
Many reference frequencies are supported by the device. If a crystal is used as the reference frequency source, the
typical required parameters are listed below:
Parameter
Drive level
Description
–
1
Min
Typ
Max
Unit
–
–
0.3
mW
–
150
Ω
ESR
Effective serial resistance
–
CO
Holder capacitance2
–
3
5
pF
CL
Load capacitance3
–
12
18
pF
CM
Motional capacitance
–
6
–
fF
1. For 32 MHz crystal.
2. If DC-coupled, the external reference signal voltage must stay within this range at all times.
3. The actual values for CO and CL are dependent on the crystal manufacturer and can be compensated for by an internal crystal calibration
capability.
60 0066 R00Hrf SiW3500 Radio Processor DS
14-49
60 0066 R00Hrf SiW3500 Radio Processor DS
C9
Antenna
L2
18nH
180pF
C8
C7
8.2pF
C11
R1
47K
C10
22pF
C3
1.5pF
0.1uF
0.1uF
L1
2.2nH
C1
C2
B1
A6
F1
A2
A4
VREFN_CAP
VREFP_CAP
IDAC
VTUNE
CHG_PUMP
RF_IO
TX_BIAS
U1
C4
18pF
XTAL_N
XTAL_P/CLK
B7
Y1
DSX321SL
3
1
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
A7
Connect D[9] to
D[10] to select
internal ROM mode.
SiW3500
VCC_OUT
VCC
VCC
VCC
VCC
VCC
VBATT_ANA
VBATT_DIG
VDD_C
VDD_C
D1
A1
B6
C4
E1
E3
VBATT
D3
L9
C11
L8
C6
1uF
(INTERNAL ROM CONFIGURATION)
C5
18pF
VSS_P
VSS_P
VSS_P_ALT
A[17]/EEPROM_SCL
A[16]/EEPROM_SDA
A[15]
A[14]
A[13]
A[12]
A[11]
A[10]
A[9]
A[8]
A[7]
A[6]
A[5]
A[4]
A[3]
A[2]
A[1]
D[15]
D[14]
D[13]
D[12]
D[11]
D[10]
D[9]
D[8]/PIO[3]
D[7]/PIO[7]
D[6]/PIO[6]
D[5]/PIO[5]
D[4]/PIO[4]
D[3]
D[2]
D[1]
D[0]
C2
1uF
A3
A5
B2
B3
B4
B5
C3
D2
D9
E2
F2
J7
E9
J8
J3
E11
J11
L5
F11
B8
K6
L7
A10
H11
A11
B11
K9
K7
C10
K10
D10
L11
A9
C9
B10
E10
K5
G11
G10
H9
K4
J9
K8
J6
J5
F9
J4
H10
A8
J10 WE_N/EEPROM_WP
L10 FCS_N
OE_N
14-50
VDD_P
VDD_P
D11
K11
VDD_P
VDD_P_ALT
L3
ADC_IN
PWR_REG_EN
PCM_CLK
PCM_SYNC
PCM_IN
PCM_OUT
AUX_TXD
EXT_WAKE
UART_RXD
UART_TXD
UART_CTS
UART_RTS
MFP[0]
MPF[1]
MFP[2]
MFP[3]
MFP[4]
MFP[5]
MFP[6]
MFP[7]
CLK32K_OUT
RESET_N
CLK32K_IN
C1
0.1uF
G2
J2
K3
K2
H3
L2
G9
C5
G3
L4
H2
H1
F3
J1
L6
F10
B9
C8
C7
C6
K1
L1
G1
HOST INTERFACE
Application Circuit
Internal ROM Version
SiW3500
Preliminary
14-51
C9
Antenna
L2
18nH
180pF
C8
C7
8.2pF
C11
R1
47K
C10
22pF
0.1uF
0.1uF
L1
2.2nH
C1
C2
B1
A6
F1
A2
A4
VREFN_CAP
VREFP_CAP
IDAC
VTUNE
CHG_PUMP
RF_IO
TX_BIAS
U1
XTAL_N
XTAL_P/CLK
U2
SiW3500
VCC_OUT
VCC
VCC
VCC
VCC
VCC
VBATT_ANA
VBATT_DIG
VDD_C
VDD_C
B7
A7
D1
A1
B6
C4
E1
E3
VBATT
D3
L9
C11
L8
RY/BY#
RESET#
VCC
BYTE#
2M or 4M FLASH
C6
1uF
(EXTERNAL FLASH CONFIGURATION)
VSS_P
VSS_P
VSS_P_ALT
A[17]/EEPROM_SCL
A[16]/EEPROM_SDA
A[15]
A[14]
A[13]
A[12]
A[11]
A[10]
A[9]
A[8]
A[7]
A[6]
A[5]
A[4]
A[3]
A[2]
A[1]
C5
18pF
Note: For 4M
Flash, use MPF[2]
for A17 pin
MFP[2]
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
GND
C4
18pF
E11
J11
L5
F11
B8
K6
L7
A10
H11
A11
B11
K9
K7
C10
K10
D10
L11
D[15]
D[14]
D[13]
D[12]
D[11]
D[10]
D[9]
D[8]/PIO[3]
D[7]/PIO[7]
D[6]/PIO[6]
D[5]/PIO[5]
D[4]/PIO[4]
D[3]
D[2]
D[1]
D[0]
WE_N/EEPROM_WP
FCS_N
OE_N
Y1
DSX321SL
1
A3
A5
B2
B3
B4
B5
C3
D2
D9
E2
F2
J7
E9
J8
J3
B2
E6
D6
C6
A6
B6
D5
C5
A5
B5
A2
C2
D2
B1
A1
C1
D1
E1
3
A17
A16
A15
A14
A13
A12
A11
A10
A9
A8
A7
A6
A5
A4
A3
A2
A1
A0
A9
C9
B10
E10
K5
G11
G10
H9
K4
J9
K8
J6
J5
F9
J4
H10
A8
J10
L10
C3
1.5pF
GND
GND
NC
NC
NC
NC
NC
G6
F5
G5
F4
G3
F3
G2
F2
E5
H5
E4
H4
H3
E3
H2
E2
A4
F1
G1
C2
1uF
H1
H6
B3
C3
D3
C4
D4
DQ15
DQ14
DQ13
DQ12
DQ11
DQ10
DQ9
DQ8
DQ7
DQ6
DQ5
DQ4
DQ3
DQ2
DQ1
DQ0
WE
CE
OE
60 0066 R00Hrf SiW3500 Radio Processor DS
VDD_P
VDD_P
D11
K11
A3
B4
F6
G4
VDD_P
VDD_P_ALT
L3
C12
0.1uF
VDD_P
PWR_REG_EN
ADC_IN
PCM_CLK
PCM_SYNC
PCM_IN
PCM_OUT
AUX_TXD
EXT_WAKE
UART_RXD
UART_TXD
UART_CTS
UART_RTS
MFP[0]
MPF[1]
MFP[2]
MFP[3]
MFP[4]
MFP[5]
MFP[6]
MFP[7]
CLK32K_OUT
RESET_N
CLK32K_IN
C1
0.1uF
G2
J2
K3
K2
H3
L2
G9
C5
G3
L4
H2
H1
F3
J1
L6
F10
B9
C8
C7
C6
K1
L1
G1
HOST INTERFACE
Application Circuit
External Flash Version
SiW3500
Preliminary
SiW3500
Preliminary
VFBGA I/O Configuration (Top View)
14-52
1
2
3
4
5
6
7
8
9
10
11
A
VCC
RF_IO
GND
TX_
BIAS
GND
VTUNE
XTAL_
P/CLK
WE_N
D[15]
A[10]
A[8]
B
IDAC
GND
GND
GND
GND
VCC
XTAL_N
A[13]
MFP[4]
D[13]
A[7]
C
VREF
P_CAP
VREF
N_CAP
GND
VCC
EXT_
WAKE
MFP[7]
MFP[6]
MFP[5]
D[14]
A[4]
VDD_C
D
VCC_
OUT
GND
VBATT_
ANA
GND
A[2]
VDD_P
E
VCC
GND
VCC
VSS_P
D[12]
A[17]
F
CHG_
PUMP
GND
MFP[0]
D[2]
MFP[3]
A[14]
G
RESET_
N
PWR_
REG_
EN
UART_
RXD
AUX_
XTD
D[9]
D[10]
H
UART_
RTS
UART_
CTS
PCM_IN
D[8]
D[0]
A[9]
J
MFP[1]
ADC_IN
VSS_P_
ALT
D[1]
D[3]
D[4]
GND
VSS_P
D[6]
FCS_N
A[16]
K
CLK_
32K_
OUT
PCM_
SYNC
PCM_
CLK
D[7]
D[11]
A[12]
A[5]
D[5]
A[6]
A[3]
VDD_P
L
CLK_
32K_
IN
PCM_
OUT
VDD_
P_ALT
UART_
TXD
A[15]
MFP[2]
A[11]
VDD_C
VBATT_
DIG
OE_N
A[1]
1
2
3
4
5
6
7
8
9
10
11
60 0066 R00Hrf SiW3500 Radio Processor DS
SiW3500
Preliminary
Packaging and Product Marking
Package Drawing
Green package, 96-Pin, 6 mm x6 mm, VFBGA Drawing and Dimensions
Symbol
A
A1
A2
A3
b
D
E
e
D1
E1
Min
0.8
0.2
Max
1.0
0.3
0.22 REF
0.45 REF
0.25
0.35
6 BSC
6 BSC
0.5 BSC
5 BSC
5 BSC
Notes:
1. Dimension b is measured at the maximum solder ball diameter, parallel to datum plane Z.
2. Datum Z is defined by the spherical crowns of the solder balls.
3. Parallelism measurement shall exclude any effect of mark on top surface of package.
4. All dimensions are in millimeters.
5. VFBGA green package solder ball material: 95.5% Sn, 4% Ag, 0.5% Cu.
60 0066 R00Hrf SiW3500 Radio Processor DS
14-53
SiW3500
Preliminary
Product Marking
96-Pin, VFBGA Drawing
Pin 1 Corner
Pin 1 Bar
SIW
4 Digit
Date Code
XXXXXXXX
LLLLL
YYWW
ARM
Trace Code
Ordering Information
Part Number
Operational
Temperature Range1
Package
96-pin VFBGA,
green package
96-pin VFBGA,
green package
Ordering
Quantity
SIW3500GIG1
Industrial
SIW3500GIG1-T13
Industrial
SiW3500DIF1
Industrial
Known good die2,
green package
Waffle pack
SiW3500DIF1-T13
Industrial
Known good die2,
green package
2,500 on 13” reel
1Industrial
429 pcs. per tray
2500 on 13” reel
temperature range: -40°C to +85°C.
2 For
additional technical details about known good die, please refer to RF Micro Devices document 60
0071 SiW3500DIF Bumped Die Manufacturing Notes.
The information in this publication is believed to be accurate and reliable. However, no responsibility
is assumed by RF Micro Devices for its use, nor for any infringement of patents, or other rights of
third parties, resulting from its use. No license is granted by implication or otherwise under any
patent or patent rights of RF Micro Devices, Inc. RF Micro Devices reserves the right to change
component circuitry, recommended application circuitry and specifications at any time without prior
notice.
RF MICRO DEVICES®, RFMD®, Optimum Technology Matching®, Enabling Wireless Connectivity™,
UltimateBlue™, and the SiW product name prefix are trademarks of RFMD, LLC. BLUETOOTH is a trademark
owned by Bluetooth SIG, Inc., U.S.A. and licensed for use by RF Micro Devices, Inc. Manufactured under license
from ARM Limited. ARM, ARM7TDMI and the ARM logo are the registered trademarks of ARM Limited in the EU
and other countries. All other trade names, trademarks and registered trademarks are the property of their
respective owners.
14-54 of 54
60 0066 R00Hrf SiW3500 Radio Processor DS