Transcript 0121.CC11xx range improvement
CC11xx Range Improvements
Richard Wallace
Presentation Abstract
• • • • • • • • • • • • • • • • Presentation Abstract Abbreviations – General – NE1 Antenna – NE2 Antenna – SS2 Antenna Out of the Box Experience – Existing range of CC11xx – Current Consumption CC1101 868/915 Reference Design Schematic Abstracts from DN017 - CC11xx 868/915 MHz RF Matching Effects of non-50ohm wideband load - Antenna Impedance Improvement Goals Calculated Expected Range for 915MHz, CC1101 New RF Network Designs – Discrete Solutions – SAW Filter Solution – Johanson Filter-Balun Solution Range Test Results Best Results Obtained Results from initial Conclusion from Range Measurements Test Results - Current Consumption Test Result Matrix Conclusions Extra Slides
Abbreviations - General
CC11xx TX RX bps PER BOMa BOMb BOMc BOMc1 BOMc_saw np CC1100, CC1101, CC1110, CC1111 and CC1150 Transmitter Receiver bits per second Packet Error Rate Existing reference design Johanson Filter-balun design (CC1110) (CC1101) Existing reference design not performed (CC1101) Extra filtering discrete balun design (CC1101) Existing reference design (CC1101)
Abbreviations – NE1 Antenna
Abbreviations – NE2 Antenna
Abbreviations – SS2 Antenna
(yellow)
Existing range of CC11xx – Out of the Box Experience Setup (250kbps, 1.3m above ground, 0dBm, Tx + Rx) CC2510 (KA) CC1110 (NE1) CC1101 (NE1)
What range do we have today ?
Distance (Line of Sight) 120m ??
??
Existing range of CC11xx – Out of the Box Experience Setup (250kbps, 1.3m above ground, 0dBm, Tx + Rx) CC2510 (KA) CC1110 (NE1) CC1101 (NE1) Distance (Line of Sight) 120m 130m 160m Area of Improvement #1: Range between 2 units implementing CC11xx is not good enough and the performance can be improved
Variation of Current Consumption - Out of the Box Experience CC1101; 915MHz, simple unmodulated TX carrier; 10dBm, all values are in mA BOM default (BOMc) #1 default (BOMc) #2 “close” measurements are close proximity to the antenna 50ohm 31,94 31,12 Open 25,18 24,87 difference 6,76 6,25 NE1 31,19 30,60 NE1 close difference 29,46 29,48 1,73 1,12 NE2 36,70 36,25 NE2 close difference 33,35 32,52 3,35 3,73 Area of Improvement #2: The design is sensitive due to antenna / load conditions. Large current consumption difference depending on the load.
CC1101 - 868/915 Reference Design Schematic
Balanced LPF for matching and reflecting harmonics. Balun (LPF/HPF) 3 pole LPF 50Ohm Differential impedance as seen from the RF-port (RF_P and RF_N) towards the antenna is 86.5 + j43 @ 868 MHz.
DC block EM revisions: rev3.2 - latest with 3 pole LPF rev3.1 - 2 pole LPF (L123, C123) low supression of 2nd harm for 3- 7dBm output power. rev2.2 - Obsolete - radiation emission problems (does not have any balanced LPF)
CC1101 - 868/915 Reference Design Schematic – Abstracts from DN017
Square wave output from chip (TX).
An ideal output signal from the CC11xx products in TX mode is a square wave signal at the RF_P and RF_N pins and a sine wave at the antenna port. To achieve this, the filterbalun must reflect the harmonics back towards the RF_P and RF_N ports. The shape of the square wave pulse depends on the impedance at the different harmonics. The current consumption in TX depends on the shape of the signal at RF_P and RF_N. Lowest possible current consumption is achieved by having the odd harmonics (3rd and 5th) reflected back.
CC1101 - 868/915 Reference Design Schematic – Abstracts from DN017
Square wave output from chip (TX).
Unexpected high current consumption in a design may be caused by incorrect or missing reflection of harmonics. The simplest way of reflecting the harmonics towards the chip is to have a differential low pass filter between the CC11xx and the balun. Ideally the series inductors, L121 and L131, will reflect harmonics towards the chips with high real part of the impedance. The low pass filter will also lower the harmonics level into the balun and reducing the risk of having unwanted radiated power through the balun and the single ended filter.
Effects of non-50ohm wideband load - Antenna Impedance
Distorted square wave output from chip (TX).
Impedance unknown at harmonic frequencies for most antenna vendors.
All RF equipment have a wideband impedance of 50 ohms so good measurements results are obtained since the design can be optimised for the wideband load of 50ohms.
However, antennas are normally adapted to 50ohms at their operating frequency but the impedance at the harmonics is not 50ohms. Depending on the antenna impedance at the harmonic frequencies; different results can be obtained from vendor to vendor since the reflected signal to the chip is distorting the square wave output due to phase change.
Ideally, the load should be capable of a mismatch and the output from the chip should not be effected.
Improvement Goals Area of Improvement #1: • Out of box experience is poor since the range between 2 units implementing CC11xx is not good enough.
Area of Improvement #2: • Improve the reference design so that the design is not so sensitive on the load conditions.
CC1101 Expected Range – 915MHz
Friis_equation_with_Ground_model
Transmitting antenna location, height over ground Receiving antenna location, height over ground Distance between antennas Frequency Signal polarity Horisontal=H, Vertical=V Transmitted power (suplied from transmitter) Gain in Transmitting antenna Gain in Receiving antenna Dielectric constant for ground (typical 18)
Index
CC1101, 915MHz, 250kbaud sensitivity = -94dBm 1.3 [m] 1.3 [m] 360 [m] 915 [MHz] V 0 [dBm] 0 [dB] 0 [dB] 18 6 -60 -70 -80 -90 -100
Free Space and Ground model
-40 0 20 40 60 80 100 120 140 160 180 200 220 240 260 280 300 320 340 360 380 -50 Friis Ground model Vertical polarisation CC1101, 915MHz, 250kbaud sensitivity = -94dBm
Distance [m]
Expected Range with perfect match: 915MHz: 360m
New RF Network Designs The following RF network concepts will be tested to see if the range can be further improved and the load variation sensitivity can be reduced: • Discrete Solution – Existing discrete solution (BOMc) – Extra filtering Discrete Balun Solution (BOMc1) • SAW Filter Solution – existing discrete balun + SAW filter (BOMc_saw) – Murata balun + SAW filter (BOM_board_2a) • Chip Filter Balun (Johanson) Solution (BOMb)
New RF Network Designs - Discrete Solutions Existing discrete solution (BOMc) Extra Filtering Discrete Balun Solution (BOMc1) Two extra series inductors LPF can be reduced for cost reductions
New RF Network Designs - Discrete Solutions • Original BOM attenuates the second harmonic by 28dB (BOMc) • BOMc1 with extra filtering components uses two additonal inductors to give additional filtering to achieve a larger attenuation of the second harmonic; expected attenuation is 50dB
New RF Network Designs – SAW Filter Solution • High Insertion loss • Outstanding supression of spurious and harmonics • Small physical size (1x1.4mm)
New RF Network Designs – SAW Filter Solution existing discrete balun + SAW filter (BOMc_saw) Murata balun + SAW filter (BOM_board_2a) – BOMc – SAFEB915MAL0F00 SAW Filter – LPF can be removed – 22nH Shunt inductor – LDB21869M20C Standard Murata Balun – SAFEB915MAL0F00 SAW Filter
New RF Network Designs – Johanson Filter-Balun Solution (BOMb) Johanson Filter balun (BOMb) • Only 2 components required !
New RF Network Designs – Johanson Filter-Balun Solution (BOMb) Simulations from Johanson Balun
Range Test Results
0dBm, 915MHz, sens optimized, 1% PER. 1.3m above ground BOMa
PER -xdBm 0dBm
500kbps CC1110
NE1 NE2 SS2
250kbps
NE1 130m NE2 190m SS2 195m
BOMb
915MHz PER 1e-2 0dBm
CC1101
NE1 NE2 SS2 NE1 160m NE2 165m SS2 -
CC1101
NE1 NE2 SS2 NE1 210m NE2 290m SS2 250m
BOMc
915MHz PER 1e-2 0dBm
BOMc_saw
915MHz PER 1e-2 0dBm
BOMc1
915MHz PER 1e-2 0dBm
CC1101
NE1 NE2 SS2 NE1 115m NE2 120m SS2 -
CC1101
NE1 NE2 SS2 NE1 160m NE2 230m SS2 250m
CC1101
NE1 NE2 SS2 NE1 110m NE2 230m SS2 240m
CC1101
NE1 NE2 SS2 NE1 160m NE2 240m SS2 250m
Best Results Obtained from Range Test Measurements Setup (CC1101, Tx + Rx; 250kbps, 0dBm) Maximum theoretical range Johanson Balun (BOMb, NE2) Original Discrete (BOMc, SS2) New Discrete (BOMc1, SS2) Original Discrete + SAW (BOMc_saw, SS2) Original Discrete with kit antenna (BOMc, NE1) Distance (Line of Sight) 360m 290m 250m 250m 240m 160m
Conclusions from Range Measurements • • • • • • • • • CC1101 compared to CC1110 has a greater range of 21% to 23% depending on antenna.
Both CC1110 & CC1101 showed a range improvement of 41% when the antenna was changed from the standard NE1 antenna to the dipole NE2 antenna.
SS2 antenna is best suited for the discrete solution. Better performance than NE2.
Caluclated range of approx 360m should be expected with 0dBm, 915MHz & 250kbps.
CC1101 has as good range as CC1000 for the same sensitivity.
NE1 antenna must be changed asap in the kit to NE2 or SS2.
With a Johansson balun the distance was increased by 32% to 35% depending on antenna used on the CC1101 setup.
Best results are with the NE2 antenna and Johnson balun solution so far.
NE2 antenna is best suited for the Johanson balun solution
Test Results - Current Consumption CC1101; 915MHz, simple unmodulated TX carrier; 10dBm BOM default (BOMc) #1 default (BOMc) #2 new discrete (BOMc1) #1 new discrete (BOMc1) #2 Johanson (BOMb) #7 Johanson (BOMb) #11 default (BOMc + SAW) #1 default (BOMc + SAW) #2 50ohm 31,94 31,12 30,73 31,16 33,75 32,37 33,10 32,36 Open 25,18 24,87 25,67 26,97 30,31 28,45 30,70 31,71 difference 6,76 6,25 5,06 4,19 3,44 3,92 2,40 0,65 NE1 31,19 30,60 31,50 32,32 32,25 31,00 37,65 36,11 NE1 close difference 29,46 29,48 32,40 34,04 29,90 28,55 36,99 35,68 1,73 1,12 0,90 1,72 2,35 2,45 0,66 0,43 all values are in mA NE2 36,70 36,25 36,28 35,18 30,72 29,75 35,17 33,67 NE2 close difference 33,35 32,52 31,57 31,58 32,55 32,25 33,45 31,98 3,35 3,73 4,71 3,60 1,83 2,50 1,72 1,69
– Effects of SAW filter can be compared with the figures highlighted in yellow
Test Result Matrix DUT Description NE1
CC1101, 0dBm, 915MHz, 250kbps, sens optimized, 1% PER
Range (m) NE2 SS2 Cost ($) 500k/y 50ohm Open Current deviation (mA, 10dB, static unmodulated TX) delta NE1 NE1 close delta NE2 NE2 close delta
Discrete Solution Standard Discrete
BOMc 160m 230m 250m
Extra Filtering Discrete
BOMc1 160m 240m 250m 0.45
31.94
25.18
0.53
30.73
25.67
6.76
31.19
5.06
31.50
29.46
32.40
1.73
36.70
0.90
36.28
33.35
3.35
31.57
4.71
SAW Filter Solution Discrete Balun + SAW
BOMc_saw
Murata Balun + SAW
BOM_Board_2_a 110m 230m 240m np np np 0.61
33.10
30.70
0.45
31.25
32.78
2.40
37.65
1.53
28.56
36.99
29.40
0.66
35.17
0.84
29.16
33.45
1.72
30.10
0.94
Johanson Filter Balun
BOMb 210m 290m 250m 0.23
33.75
30.31
3.44
32.25
29.90
2.35
30.72
32.55
1.83
• Cost estimation include pick & place assembly cost, only RF network is included
Cost Calculations
All the prices are based upon information from the component vendors:
• 0.002 USD • 0.007 USD • 0.049 USD • 0.070 USD • 0.160 USD • 0.190 USD • 0.250 USD • 0.300 USD
0402 Murata Capacitor (COG, pF) Multi-Layer 0402 Murata Inductor Wire-Wound 0402 Murata Inductor Murata Balun (500k/year) Johanson Filter-Balun (500k / year) Johanson Filter-Balun (50k / year) Murata SAW Filter (500k/year) Murata SAW Filter (500k/year)
• • 0.030 USD
Pick & Place Assembly Cost (per component)
Conclusions
New application in-designs: Discrete Solution:
•
Lowest component cost , good range, but susceptible to load changes
• Extra filtering solution only improved load susceptibility slightly, no range
improvement compared to standard discrete solution (at the moment). SAW filter Solution:
• with discrete balun: highest cost, good range,
not susceptible to load variations
• with Murata balun:
low total cost , good range, not susceptible to load variations and compact solution Johanson Filter-Balun Solution:
•
Lowest total cost , best range , not least susceptible to load variations, best all-round solution .
• Only two components, minor risk for in-design errors
Out of box Experience - Evaluation Kit:
• New Antenna (NE2 or SS2) will be replacing old antenna (NE1); range
improvement of >41% with new antenna.
Extra Slides - Current Consumption