AN305 - Infineon

B GT2 4 MT R11
User 's Gu ide t o B G T24 MT R1 1
24 G Hz R adar
Applic atio n N ote A N 305
Revision: Rev. 1.0
2012-11-15
RF and P r otecti on D evic es
Edition 2012-11-15
Published by
Infineon Technologies AG
81726 Munich, Germany
© 2012 Infineon Technologies AG
All Rights Reserved.
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BGT24MTR11
User's Guide
Application Note AN305
Revision History: 2012-11-15
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MICROTEC™, NUCLEUS™ of Mentor Graphics Corporation. Mifare™ of NXP. MIPI™ of MIPI Alliance, Inc.
MIPS™ of MIPS Technologies, Inc., USA. muRata™ of MURATA MANUFACTURING CO. OmniVision™ of
OmniVision Technologies, Inc. Openwave™ Openwave Systems Inc. RED HAT™ Red Hat, Inc. RFMD™ RF
Micro Devices, Inc. SIRIUS™ of Sirius Sattelite Radio Inc. SOLARIS™ of Sun Microsystems, Inc. SPANSION™
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of Diodes Zetex Limited.
Last Trademarks Update 2009-10-19
Application Note AN305, Rev. 1.0
3 / 15
2012-11-15
BGT24MTR11
User's Guide
List of Content, Figures and Tables
Table of Content
1
Introduction ........................................................................................................................................ 5
2
Overview ............................................................................................................................................. 5
3
3.1
3.2
3.2.1
3.2.2
VCO Section ........................................................................................................................................ 6
Tuning Voltage Inputs .......................................................................................................................... 6
Prescalers ............................................................................................................................................ 8
Divide-by-16 Prescaler ......................................................................................................................... 8
Divide-by-65536 Prescaler ................................................................................................................... 8
4
4.1
4.1.1
4.1.1.1
4.1.1.2
4.2
Transmitter Section ........................................................................................................................... 9
TX Section ............................................................................................................................................ 9
Enabling and Disabling of the Output Power ..................................................................................... 10
Enabling/disabling via the SPI bus. .................................................................................................... 10
Enabling/disabling via the TXOFF pin. ............................................................................................... 10
LO Section .......................................................................................................................................... 11
5
5.1
5.2
Receiver Section .............................................................................................................................. 11
Low Noise Amplifier............................................................................................................................ 11
Mixer ................................................................................................................................................... 11
6
6.1
6.2
Sensors ............................................................................................................................................. 12
Power Sensors ................................................................................................................................... 12
Temperature Sensor .......................................................................................................................... 13
Authors
14
List of Figures
Figure 1
Figure 2
Figure 3
Figure 4
Figure 5
Figure 6
Figure 7
Figure 8
BGT24MTR11 block diagram ............................................................................................................... 5
VCO frequency vs. tuning voltage VFINE = VCOARSE and temperature ................................................... 6
3D plot: Output frequency vs. VCOARSE and VFINE ................................................................................. 7
2D plot: Output voltage vs. VCOARSE and VFINE ...................................................................................... 7
Termination of Div16 outputs ............................................................................................................... 8
TX output power vs. frequency for different temperatures ................................................................. 10
Transfer characteristics of power sensors ......................................................................................... 12
Transfer characteristics of temperature sensor ................................................................................. 13
List of Tables
Table 1
Table 2
Output power reduction ........................................................................................................................ 9
Truth table for analog multiplexer ....................................................................................................... 12
Application Note AN305, Rev. 1.0
4 / 15
2012-11-15
BGT24MTR11
User's Guide
Introduction
1
Introduction
This document provides supplementary information on how to use BGT24MTR11 that you may not completely
find in the datasheet.
BGT24MTR11 is the lead product of Infineon’s BGT24-series of 24 GHz radar transceiver products and serves
here as an example for all BGT24 products in this application note. All building blocks of BGT24MTR11
described here can be found on the other two products, BGT24MTR12 and BGT24MR2 as well. The additional
information in this application note is valid for these products as well.
2
Overview
The picture below shows the internal block diagram of BGT24MTR11.
Q1 Q1N
SI CS CLK
Q2
3
TX
Power
Sensor
SPI
/65536
2
AMUX
ANA
2
TX
TXX
PA
VCCTEMP
TEMP
Temp.
Sensor
FINE
/16
TXOFF
Buffer
LO
MPA
COARSE
LO
POWER
SENSOR
IFQ
IFQX
90°
LO
Buffer
PPF*
LNA
RFIN
0°
IFI
IFIX
* Poly Phase Filter
BGT24MTR11_Chip_BID.vsd
Figure 1
BGT24MTR11 block diagram
The following sub-sections of the block diagram will be covered in this application note:




Voltage controlled oscillator (VCO) and prescalers
Transmitter chain including both TX and LO outputs
Reciver chain including LNA and mixer
On-chip sensors
Application Note AN305, Rev. 1.0
5 / 15
2012-11-15
BGT24MTR11
User's Guide
VCO Section
3
VCO Section
BGT24MTR11’s signal generation section consists of a free-running VCO with two separate tuning voltage
inputs followed by a buffer amplifer to reduce frequency pulling effects. Two prescalers are available to monitor
the frequency of oscillation. The first prescaler devides the transmitted frequency by 16, the second prescaler
further reduces the output of the first one by a factor of 65536.
3.1
Tuning Voltage Inputs
BGT24MTR11 has two inputs for tuning the VCO’s frequency of oscillation, FINE (pin 4) and COARSE (pin 5).
Both inputs can be used independently of each other to adjust the frequency output. As the pin names imply,
COARSE has a steeper tuning slope compared to FINE.
If there is only one voltage available for tuning the VCO it is possible to connect both pins to this single voltage
source. The resulting tuning sensitivity will be then the sum of the sensitivities of the respective pins.
Both tuning pins are connected internally via a pull-up resistor to Vcc. This means that when a pin is left open, it
will be internally at Vcc. So if both pins are left open the oscillator will be around 26 GHz at room temperature.
Note: It is mandatory for each of the two pins to be at a voltage equal or higher than 0.5 V. If any voltage at the
pins drops below that voltage level the oscillator will fail to work. This might lead to problems when starting
a control loop and the loop’s control output voltage at the start is below 0.5V. In this case some additional
DC voltage needs to be present at the tuning inputs.
It is possible to cover the whole 24 GHz ISM band with tuning voltages between 0.5 V and 3.3 V - both over the
device’s specified temperature range and production related device variations.
Figure 2 shows the temperature behavior of the VCO. The measurement was conducted with both tuning pins,
COARSE and FINE, connected together.
Frequency vs. Vfine = Vcoarse and Temperture
27
26
Frequency / GHz
25
24
-40°C
23
25°C
85°C
105°C
22
125°C
21
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
5.5
Tuning Voltage / V
Figure 2
VCO frequency vs. tuning voltage VFINE = VCOARSE and temperature
Below are two graphs that show how the the frequency output of the oscillator behaves for different pairs of
VCOARSE and VFINE.
Application Note AN305, Rev. 1.0
6 / 15
2012-11-15
BGT24MTR11
User's Guide
VCO Section
Figure 3
3D plot: Output frequency vs. VCOARSE and VFINE
25°C
fTX < 23.5GHz
3.25
23.5GHz  fTX < 24.0GHz
24.0GHz  fTX < 24.5GHz
3
24.5GHz  fTX < 25.0GHz
2.75
25.0GHz  fTX < 25.5GHz
2.5
25.5GHz  fTX < 26.0GHz
Vcoarse (V)
2.25
2
1.75
1.5
1.25
1
0.75
0.5
0.25
0
0
Figure 4
0.25
0.5
0.75
1
1.25
1.5
1.75
Vfine (V)
2
2.25
2.5
2.75
3
3.25
2D plot: Output voltage vs. VCOARSE and VFINE
Application Note AN305, Rev. 1.0
7 / 15
2012-11-15
BGT24MTR11
User's Guide
VCO Section
3.2
Prescalers
BGT24MTR11 has two cascaded built-in prescalers. The first prescaler divides the oscillator’s frequency by 16,
the second reduces the output of the first one by the factor of 65536 – resulting in a total division factor of
1,048,576.
3.2.1
Divide-by-16 Prescaler
This first prescaler divides the VCO’s frequency of oscillation by the factor of 16. So at a given VCO frequency
of 24 GHz the prescaler’s output frequency is 1.5 GHz. This is a convenient frequency to feed into RF-PLLs.
The output frequency is fed differentially to pins 31 and 1 (Q1, Q1N). The differential port impedance is 100 .
Note: For proper operation of the prescaler both output pins need to be terminated by 50 . As there is DC
present at the two output pins a coupling capacitor will be necessary if the termination does not have a
DC-blocking circuit already implemented, (e.g. a blocking capacitor at a PLL’s input).
In case a PLL does not support differential inputs it is possible to use any of the two outputs and terminate the
unused one.
TEMP 30
31
Q1
32 VEE
2
3
VEE
1
Q2
Q1N
50Ω
50Ω
BGT24MTR11_Q1_connect.vsd
Figure 5
Termination of Div16 outputs
This prescaler may be disabled by setting SPI data bit 5 (DIS_DIV16) to HIGH.
3.2.2
Divide-by-65536 Prescaler
This prescaler is fed by the divide-by-16 prescaler’s output frequency and reduces it furtherly by the factor of
65536 resulting in a total reduction factor of 1,048,576. This means a 24 GHz VCO signal will result in an output
square wave signal of approximately 23 kHz at pin 2 (Q2).
This 23 kHz output signal can be monitored via a microcontroller’s timer input, for example, and then be used
together with the microcontrollers DAC or PWM output to create a software loop to control the VCO’s output
frequency.
Note: For proper operation of this prescaler it is mandatory that the divide-by-16 prescaler is enabled. Otherwise
the divide-by-65536 will not get an input signal and will produce false output.
This prescaler may be disabled by setting SPI data bit 6 (DIS_DIV64k) to HIGH.
Application Note AN305, Rev. 1.0
8 / 15
2012-11-15
BGT24MTR11
User's Guide
Transmitter Section
4
Transmitter Section
This chapter describes the functionalities of the main power amplifier (PA in the block diagram) that provides the
ouput for transmitting the actual radar signal at the TX output as well as the medium power amplifier (MPA) that
provides the signal at the LO output.
4.1
TX Section
The TX output signal is provided via TX and TXX pins (pin 22 and 23). It is a differential output signal with a load
impedance of 100 , given that the off-chip compensation structures, shown in the data sheet, are in place.
Ideally the TX outputs can be used directly with an antenna that has differential 100  inputs. In case of singleended antennas it will be necessary to use a balun. If the antenna is single-ended 50  then there is also the
option to terminate one of the TX outputs with 50  and use the other one directly as a 50  output port.
However, this will reduce the available output power by 3 dB.
Note: It is not recommended to create a 100  single-ended output signal by grounding one of the TX pins.
The TX output power level can be adjusted via settings in the SPI data register as shown in the table below.
Table 1
Output power reduction
SPI Data Register
Reduction of output power relative to
maximum output power / dB
Bit 2
Bit 1
Bit 0
0
0
0
0
0
0
1
0.4
0
1
0
0.8
0
1
1
1.4
1
0
0
2.5
1
0
1
4
1
1
0
6
1
1
1
9
To mitigate the roll-off of output power at high temperatures it is possible to set SPI data bit 3 (PC1_BUF, High
TX buffer output power) to HIGH. This buffer is not explicitily shown in the block diagram in Figure 1 on page 5.
At room temperature there is only an increase of 0.2 dB in the maximum TX output power.
Output power plotted versus frequency for different temperatures can be found in the figure below. The TX
buffer was in high output power mode during this measurement.
Application Note AN305, Rev. 1.0
9 / 15
2012-11-15
BGT24MTR11
User's Guide
Transmitter Section
TX Output Power vs. Frequency and Temperature
11
-40°C
Output Power / dBm
10.5
25°C
10
75°C
9.5
125°C
9
8.5
8
7.5
7
6.5
6
5.5
5
24
24.05
24.1
24.15
Frequency / GHz
Figure 6
TX output power vs. frequency for different temperatures
4.1.1
Enabling and Disabling of the Output Power
24.2
24.25
The TX outputs are disabled by default after powering-up the IC. This is to make sure that the output frequency
can be stabilized before actually transmitting a signal.
Note: Disabling the TX outputs will not reduce power consumption as all IC-internal blocks will still be running.
TX outputs are switched to an internal load when disabled. This keeps the power dissipation at a constant
level and therefore keeps the chip temperature constant. Abrupt changes in temperature would cause the
VCO’s frequency to jump to a different value which might lead to violation of the band limits before the
frequency control loop can re-lock the frequency again.
There are two possibilities to turn on and off the TX ouput power. The first is via the SPI bus and the second is
using the TXOFF pin.
4.1.1.1
Enabling/disabling via the SPI bus.
To enable the power output SPI data bit 12 (DIS_PA) needs to be set to LOW and to disable the power it needs
to be set to HIGH. If you use this method, please connect the TXOFF pin to ground.
4.1.1.2
Enabling/disabling via the TXOFF pin.
Using the TXOFF pin (pin 26) for swiching on/off or generating transmit pulses allow considerably shorter
switching times compared to using the SPI bus.
In this mode it is necessary to first set SPI data bit 12 to LOW and thus generally activating the TX outputs. After
that applying a voltage below 0.5 V to TXOFF will enable the TX outputs and a voltage higher than 1.5 V will
disable the TX outputs.
Application Note AN305, Rev. 1.0
10 / 15
2012-11-15
BGT24MTR11
User's Guide
Receiver Section
4.2
LO Section
BGT24MTR11 was designed to be used in monostatic radars. These radars are only capable of detecting a
target’s distance and speed, but not the angle of the target’s position relative to the antenna. It is possible,
though, to determine this angle when using additional RX-antennas and receiver chains. In this case the
BGT24MR2 offers two additional receiver chains in one package to build a system with three RX-antennas.
These external receiver chains need a local oscillator input which can be taken from BGT24MTR11’s LO output
(LO, pin 28).
In case the system needs one TX channel and two RX channels, Infineon offers BGT24MTR12 as a completely
integrated device especially for that application.
The LO pin may also be used as an alternative TX output in case the minimum TX output power is still too high
for the intended application. It must be noted, however, that the LO output can not be disabled unlike the TX
output.
If the proposed off-chip compensation structures described in the datasheet are implemented, the LO output
has a load impedance of 50 .
The typical output power of the LO pin is 0 dBm if the LO buffer is set to high output power mode. This can be
done by setting bit 4 (PC2_BUF) of the SPI register to HIGH. In low output power mode the output power is
reduced by 3.5 dB.
In case the LO output is not required, this pin can be left open.
5
Receiver Section
BGT24MTR11’s receiver section consists of two major blocks, the low noise amplifer (LNA) and the mixer.
5.1
Low Noise Amplifier
The LNA has a single-ended RF input with a port impedance of 50 , provided that the suggested off-chip
compensation structures are present on the PCB.
It is possible to reduce the LNA’s gain by setting SPI data bit 15 (GS) to high. The gain is then reduced by 6 dB.
5.2
Mixer
BGT24MTR11 features a homodyne quadrature downconversion mixer. RF input is provided by the LNA and
the LO signal is taken from the VCO’s output, isolated by a buffer amplifier. A RC polyphase filter is used for LO
quadrature phase generation.
The mixer converts the 24 GHz signals directly down to zero-IF and offers differential in-phase and quadrature
IF output signals. Each port has an impedance of 800  and may be connected directly to loads greater than
10 k. Low ohmic loads need to have an coupling capacitor in place as there is a DC-voltage present at each
IF-output. This DC-voltage is typically 2.3 V with an offset of ±0.2 V depending on the received power and the
amount of LO leakage in the system. The maximum AC-swing, resulting from an RX signal with a power level
close to the LNA’s input compression point is 0.6 V peak-peak. When deeply in saturation the AC-swing can go
up to 1 V peak-peak.
Application Note AN305, Rev. 1.0
11 / 15
2012-11-15
BGT24MTR11
User's Guide
Sensors
6
Sensors
BGT24MTR11 has three built in sensors for measuring TX-power, LO-power and chip temperature
All three sensors offer their readings via analog output voltages, which can be accessed via a multiplexer that
connects the single output voltages to the ANA pin (pin 25).
The table below shows which bits in the SPI data register need to be set to select the different sensor readings
at ANA.
Table 2
Truth table for analog multiplexer
Output signal at ANA
POUT,TX
AMUX2 (bit 11)
low
AMUX1 (bit 8)
low
AMUX0 (bit 7)
low
PREF,TX
low
low
high
POUT,LO
low
high
low
PREF,LO
low
high
high
VTEMP
high
low
low
6.1
Power Sensors
For output power measurement, peak voltage detectors are connected to the output of the TX power amplifier
and to the LO medium power amplifier. To eliminate temperature and supply voltage variations, a reference
output voltage VREF is available through the ANA output for the TX and LO power sensor. The compensated
detector output voltage is given by the difference between V OUT and VREF for both power sensors. This voltage
difference is proportional to the RF voltage swing at the individual amplifier outputs, its characteristic is nondirectional.
Note: The actual voltage output of the power sensors is strongly dependant on the terminations of the amplifier
outputs since the power sensors are actually peak voltage detectors.
Output Power vs. DV = (VOUT,TX - VREF,TX)
10
9
8
7
6
Pout / dBm
5
4
3
Measurement
2
Model
1
0
-1
Transfer Function
Pout/dBm = 5.24*ln(DV/mV) - 23.74
-2
-3
-4
50
100
150
200
250
300
350
400
DV / mV
Figure 7
Transfer characteristics of power sensors
Application Note AN305, Rev. 1.0
12 / 15
2012-11-15
BGT24MTR11
User's Guide
Sensors
6.2
Temperature Sensor
Monitoring of the chip temperature is provided by the on-chip temperature sensor which delivers temperatureproportional voltage to the TEMP output pin (pin 30). Alternatively the output voltage can be read out via the
analog multiplexer output ANA (pin 25). The temperature sensor can be independently biased through
VCCTEMP (pin 29). This makes it possible to measure the chip temperature while the main supply of the
transceiver is switched off.
Chip Temperature vs. DVtemp
130
110
90
Temperature / °C
70
50
Measurement
30
Model
10
-10
Transfer Function
T/°C = 0.22*(DVtemp/mV) - 289
-30
-50
0
Figure 8
100
200
300
400
500
600
Vtemp / mV
700
800
900
1000
Transfer characteristics of temperature sensor
Application Note AN305, Rev. 1.0
13 / 15
2012-11-15
BGT24MTR11
User's Guide
Authors
Authors
Dietmar Stolz, Staff Engineer of Business Unit “RF and Protection Devices”
Application Note AN305, Rev. 1.0
14 / 15
2012-11-15
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Published by Infineon Technologies AG
AN305