AN4133 Application note

Transcription

1 Application note Using the SPIRIT1 transceiver under ARIB STD-T108 in the 920 MHz band Introduction By Placido De Vita SPIRIT1 is a very low power RF transceiver, intended for RF wireless applications in the sub-1 GHz band. It is designed to operate both in the license-free ISM and SRD frequency bands at 169, 315, 433, 868, 915 and 920 MHz. The Japanese Association of Radio Industries and Businesses (ARIB) was established in response to several trends such as the growing internationalization of telecommunications, the convergence of telecommunications and broadcasting and the need for promotion of radio-related industries. The ARIB organism defines the basic technical requirements for standard specifications of radio equipment. This application note outlines the expected performance when using the 1 under ARIB STD-T108 (see References on page 33) in the 920 MHz band. For details on the regulatory limits in the 920 MHz frequency band, please refer to the ARIB STD-T108 regulation in References on page 33. These can be downloaded from July 2012 Doc ID Rev 1 1/35

2 Contents AN4133 Contents 1 An overview of ARIB STD-T108 regulation Convenience radio stations Low-power radio stations Application circuit Transmitter Adjacent channel leakage power Permissible values for unwanted emission intensity Receiver Limit on secondary radiated emission References Revision history /35 Doc ID Rev 1

3 List of tables List of tables Table 1. Permissible values for unwanted emission intensity Table 2. Limit on secondary radiated emissions, etc. at receiver Table 3. Permissible values for unwanted emission intensity Table 4. Limit on secondary radiated emissions, etc. at receiver Table 5. Document revision history Doc ID Rev 1 3/35

4 List of figures AN4133 List of figures Figure 1. SPIRIT1 application daughterboard Figure 2. SPIRIT1 application daughterboard plugged into the motherboard Figure 3. Daughterboard schematic Figure 4. Convenience radio station channel mask of a radio channel whose frequency is from MHz to MHz Figure 5. Convenience radio station channel mask of a radio channel at 922 MHz Figure 6. Convenience radio station channel mask of a radio channel whose frequency is from MHz to MHz Figure 7. Convenience radio station channel mask of a radio channel at 923 MHz Figure 8. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz Figure 9. Low-power radio station channel mask of a radio channel at MHz Figure 10. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz Figure 11. Low-power radio station channel mask of a radio channel at MHz Figure 12. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz (antenna power is 1 mw or less)l Figure 13. Low-power radio station channel mask of a radio channel at 928 MHz Figure 14. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz (antenna power is more than 1 mw and 20 mw or less).. 18 Figure 15. Low-power radio station channel mask of a radio channel at 925 MHz Figure 16. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz Figure 17. Low-power radio station channel mask of a radio channel at 929 MHz Figure 18. Convenience radio station emission in the MHz bandwidth Figure 19. Convenience radio station emission in the MHz bandwidth Figure 20. Convenience radio station emission in the MHz bandwidth Figure 21. Convenience radio station emission in the MHz bandwidth Figure 22. Convenience radio station emission in the MHz bandwidth Figure 23. Convenience radio station emission in the MHz bandwidth Figure 24. Convenience radio station emission in the MHz bandwidth Figure 25. Convenience radio station emission in the GHz bandwidth Figure 26. Convenience radio station emission in the Hz bandwidth Figure 27. Low-power radio station emission in the MHz bandwidth Figure 28. Low-power radio station emission in the MHz bandwidth Figure 29. Low-power radio station emission in the MHz bandwidth Figure 30. Low-power radio station emission in the MHz bandwidth Figure 31. Low-power radio station emission in the MHz bandwidth Figure 32. Low-power radio station emission in the GHz bandwidth Figure 33. Low-power radio station emission in the GHz bandwidth Figure 34. Receiver radiated emission in the MHz bandwidth Figure 35. Receiver radiated emission in the MHz bandwidth Figure 36. Receiver radiated emission in the MHz bandwidth Figure 37. Receiver radiated emission in the MHz bandwidth Figure 38. Receiver radiated emission in the MHz bandwidth Figure 39. Receiver radiated emission in the 1-6 GHz bandwidth /35 Doc ID Rev 1

5 An overview of ARIB STD-T108 regulation 1 An overview of ARIB STD-T108 regulation Radio equipment defined in this standard utilizes 915 to 930 MHz bandwidth. The ARIB STD-T108 defines two different types of possible categories of application: 1. Convenience radio stations 2. Low-power radio stations A short description of the two different categories is given in the following sections. The main difference concerns the output power and band frequency used. 1.1 Convenience radio stations Devices that operate in convenience radio stations will work in using either a simplex, duplex, or semi-duplex broadcast method. The contents of communications are primarily the signals for telemetry, telecontrol and data transmission systems. The operating frequency band is between MHz and MHz. The maximum permitted antenna power is 250 mw (+24 dbm on a 50 ohm load, +27 dbm EIRP considering an antenna of 3 dbi gain). A radio channel consists of up to 5 consecutive unit radio channels which are defined such that their center frequency is located from MHz to MHz with 200 khz separation and a bandwidth of 200 khz. There aren't specific requirements for the modulation method, while the permissible value for occupied bandwidth is (200 x n) khz or less, where n is the number of unit radio channels constituting the entire radio channel and is an integer from 1 to 5. An adjacent channel leakage power is permitted: two different channel masks are defined, one for systems that work in the MHz to MHz band and a second one for the systems that work in the to MHz band. For the two different masks refer to the figures 3-1 and 3-2 of the ARIB STD-T108 regulation cited in References on page 33. For the transmitter a permissible value for unwanted emission intensity is defined (see Table 1). For the receiver a limit for the secondary radiated emissions is defined (see Table 2). Table 1. Permissible values for unwanted emission intensity Frequency band Spurious emission strength (average power) Reference bandwidth f <= 710 MHz -36 dbm 100 khz 710 MHz < f 900 MHz -55 dbm 1 MHz 900 MHz < f 915 MHz -55 dbm 100 khz 915 MHz < f MHz -36 dbm 100 khz MHz < f MHz (except for f-fc ( xn) khz) -55 dbm 100 khz MHz < f 930 MHz -36 dbm 100 khz 930 MHz < f 1000 MHz -55 dbm 100 khz 1000 MHz < f 1215 MHz -45 dbm 1 MHz 1215 MHz < f dbm 1 MHz Doc ID Rev 1 5/35

6 An overview of ARIB STD-T108 regulation AN4133 Table 2. Limit on secondary radiated emissions, etc. at receiver Frequency band Limit on secondary radiated emissions, etc. (antenna input) Reference bandwidth f 710 MHz -54 dbm 100 khz 710 MHz < f 900 MHz -55 dbm 1 MHz 900 MHz < f 915 MHz -55 dbm 100 khz 915 MHz < f 930 MHz -54 dbm 100 khz 930 MHz < f 1000 MHz -55 dbm 100 khz 1000 MHz < f -47 dbm 1 MHz 1.2 Low-power radio stations Low-power radio stations differ from convenience radio stations in output power and usable frequency band. Regarding the output power, two different values are permitted as follows. An output power of 1 mw (0 dbm on a 50 ohm load, +3 dbm EIRP considering an antenna of 3 dbi gain) is permitted in the band greater than or equal to MHz to less than or equal to MHz, and greater than or equal to MHz and less than or equal to MHz. An output power of 20 mw (+13 dbm on a 50 ohm load, +16 dbm EIRP considering an antenna of 3 dbi gain) is permitted in the band greater than or equal to MHz to less than or equal to MHz. As for convenience radio stations, an entire radio channel consists of up to 5 consecutive unit radio channels which are defined such that their center frequency is located from MHz to MHz and from MHz to MHz with 200 khz separation and a bandwidth of 200 khz, or which are defined such that their center frequency is located from MHz to MHz with 100 khz separation and a bandwidth of 100 khz. There aren't specific requirements for the modulation method, while the permissible value for the occupied bandwidth is (200 x n) khz or less, where n is the number of unit radio channels constituting the entire radio channel and is an integer from 1 to 5. In the case that the center frequency is from MHz to MHz, it shall be (100 x n) khz or less. An adjacent channel leakage power is permitted: five different channel masks are defined, functions of the usable bandwidth and of the output power. For the five different masks refer to the figures 3-1 to 3-5 of the ARIB STD-T108 regulation, see References on page 33. For the transmitter a permissible value for unwanted emission intensity is defined (see Table 3). For the receiver a limit for the secondary radiated emissions is defined (see Table 4). 6/35 Doc ID Rev 1

7 An overview of ARIB STD-T108 regulation Table 3. Permissible values for unwanted emission intensity Frequency band Spurious emission strength (average power) Reference bandwidth f 710 MHz -36 dbm 100 khz 710 MHz < f 900 MHz -55 dbm 1 MHz 900 MHz < f 915 MHz -55 dbm 100 khz 915 MHz < f 930 MHz (Except for f-fc ( xn) khz if bandwidth of unit radio channel is 200 khz, except for f-fc <= (100+50xn) khz if the bandwidth of unit radio channel is 100 khz. Except for f-fc <= ( xn) khz if frequency band is MHz f MHz and MHz f MHz. Where n is a number of unit radio channels constituting the radio channel and is an integer from 1 to 5). -36 dbm 100 khz 930 MHz < f 1000 MHz -55 dbm 100 khz 1000 MHz < f 1215 MHz -45 dbm 1 MHz 1215 MHz < f dbm 1 MHz Table 4. Limit on secondary radiated emissions, etc. at receiver Frequency band Limit on secondary radiated emissions, etc. (antenna input) Reference bandwidth f 710 MHz -54 dbm 100 khz 710 MHz < f 900 MHz -55 dbm 1 MHz 900 MHz < f 915 MHz -55 dbm 100 khz 915 MHz < f 930 MHz -54 dbm 100 khz 930 MHz < f 1000 MHz -55 dbm 100 khz 1000 MHz < f -47 dbm 1 MHz Doc ID Rev 1 7/35

8 Application circuit AN Application circuit Figure 1 shows the SPIRIT1 application board. The application is composed of two boards: a daughterboard and a motherboard. The daughterboard holds the SPIRIT1 with the circuits necessary for operation. In order to function properly the daughterboard has to be plugged into the motherboard (see Figure 2) using two header 5x2 connectors (J6 and J7). The motherboard is provided with an STM32L152VBT6 microcontroller to correctly program the transceiver. The microcontroller is programmed with firmware developed for the SPIRIT1 application. A graphical user interface (GUI) has been developed to correctly program the SPIRIT1. The daughterboard is provided with a 52 MHz crystal to provide the correct oscillator to the SPIRIT1. The SPIRIT1 has an internal SMPS that drastically reduces power consumption making the SPIRIT1 the best in class for the application in this bandwidth. The SMPS is fed from the battery (1.8 V to 3.6 V) and provides a programmable voltage (1.4 V usually) to the device. An SMA connector is present to connect the board to the antenna or to the instrumentation to verify the correct functionality and verify the ETSI standard request. A few passive components (inductors and capacitors) are used for matching/filtering of the power amplifier (PA) and balun network for the receiver. To reduce the application cost the SPIRIT1 is designed to work without an external antenna switch. This daughterboard is designed to show the functionality of the SPIRIT1 in this condition. Of course an application with antenna switch can be implemented, but this isn't described in this document. Figure 1. SPIRIT1 application daughterboard 8/35 Doc ID Rev 1

9 Application circuit Figure 2. SPIRIT1 application daughterboard plugged into the motherboard Doc ID Rev 1 9/35

10 Application circuit Doc ID Rev 1 10/35 Figure 3. Daughterboard schematic SDn GPIO0 GPIO1 GPIO2 GPIO3 SCLK SDO SDI CSn DUMMY3 DUMMY3 SPIRIT_DUMMY2 SPIRIT_DUMMY1 VCC_RF 3V3 3V3 NX3225GA-xxMHz (XTAL) B0=169MHz B1=315MHz B2=433MHz B3=868MHz Mount resistor relative to used band B3=915MHz B3=920MHz C10 C_10P_0402_C0G_J_50 C10 C_10P_0402_C0G_J_50 C6 C6 L2 L_TBD_0402 L2 L_TBD_0402 R12 R_TBD_0402 R12 R_TBD_0402 Y1 XTAL Y1 XTAL J7 HEADER 5X2 J7 HEADER 5X L5 L_TBD_0402 L5 L_TBD_0402 J6 HEADER 5X2 J6 HEADER 5X C20 C_1U_0603_X7R_K_6V3 C20 C_1U_0603_X7R_K_6V3 C11 C_1U_0603_X7R_K_6V3 C11 C_1U_0603_X7R_K_6V3 L7 L_10U_0805 L7 L_10U_0805 L4 L_TBD_0402 L4 L_TBD_0402 C8 C8 C19 C19 U1 SPIRIT1_2 U1 SPIRIT1_2 GPIO_0 1 SDO 2 SDI 3 SCLK 4 CSn 5 VBAT2 8 XOUT 6 XIN 7 RXP 9 RXN 10 REXT 11 TX 12 SMPS2 13 SMPS1 14 VBAT1 16 SDn 15 VREG 17 GPIO_3 18 GPIO_2 19 GPIO_1 20 GND 21 L6 L_TBD_0402 L6 L_TBD_0402 R7 R_0R0_0402 R7 R_0R0_0402 L9 L_TBD_0402 L9 L_TBD_0402 L0 L_TBD_0402_50M L0 L_TBD_0402_50M R6 R_0R0_0402 R6 R_0R0_0402 L1 L_TBD_0402 L1 L_TBD_0402 R9 R_0R0_0402 R9 R_0R0_0402 R10 R_0R0_0402 R10 R_0R0_0402 R13 R_TBD_0402 R13 R_TBD_0402 R8 R_0R0_0402 R8 R_0R0_0402 C22 C_330p_0402_C0G C22 C_330p_0402_C0G C13 C_TBD_0402_X7R C13 C_TBD_0402_X7R C15 C15 R11 R_0R0_0402 R11 R_0R0_0402 C7 C7 C1 C1 C4 C4 C12 C_100n_0402_X7R C12 C_100n_0402_X7R C2 C2 C21 C_100p_0402_C0G C21 C_100p_0402_C0G C0 C_100n_0402_X7R C0 C_100n_0402_X7R C9 C_12P_0402_C0G_J_50 C9 C_12P_0402_C0G_J_50 L3 L_TBD_0402 L3 L_TBD_0402 L8 L_TBD_0402 L8 L_TBD_0402 C3 C3 C14 C14 C5 C5 J1 RF_IN/OUT J1 RF_IN/OUT

11 Transmitter 3 Transmitter All the measurements given are measured under the following conditions: Tc = 25 C, Vdd = 3.0 V, f = 922 MHz (middle frequency of the bandwidth used), unless otherwise specified. The maximum output power of the SPIRIT1 in this band is 10 dbm, so all the measurements for the convenience radio stations and low-power radio stations with +24 dbm or +13 dbm output power will be performed at +10 dbm. Low-power radio stations with output power of 0 dbm will be performed with the correct output power. A radio channel consists of up to 5 consecutive unit radio channels which are defined such that their center frequency is located from MHz to MHz with 200 khz separation and a bandwidth of 200 khz. SPIRIT1 fully supports the center frequency, separation and bandwidth requirements. No measurement in that sense will be done. There aren't specific requirements for the modulation method, while the permissible value for the occupied bandwidth is (200 x n) khz or less, where n is the number of unit radio channels constituting the entire radio channel and is an integer from 1 to 5. The measurement in this case will be done with a GFSK (BT = 0.5) modulation with 100 kbps data rate, 50 khz frequency deviation. Different combinations of modulation, data rate and frequency deviation creates signals that have a bandwidth lower than 200 khz: a specific check has to be done for each case. There are no specific requirements in the standard about setting the detector, resolution bandwidth (RBW) or video bandwidth (VBW) of the spectrum analyzer. The detector will be set to peak, the resolution and video bandwidths will be set sufficiently large to ensure the correctness of the measurement, and the display will be set to peak hold. 3.1 Adjacent channel leakage power The adjacent channel leakage power is defined as the amount of the modulated RF signal power which falls within a given adjacent channel. This power is the sum of the mean power produced by the modulation, hum and noise of the transmitter. Different masks are defined for the two types of operating modes. For the convenience radio stations the masks given in Figure 4 and 6 are defined. The first one defines the channel mask of a radio channel whose frequency is from MHz to MHz. The second one defines the channel mask of a radio channel whose frequency is from MHz to MHz. The max output power permitted for the convenience radio station is 250 mw (+24 dbm), the SPIRIT1 doesn't support this output power, so the mask compliance is verified with an output power of 10 dbm. An external PA should be used to reach the maximum output power. Figure 5 and 7 show the compliance measurement with the two masks and that the SPIRIT1 complies. If an external power amplifier is used to burst the output power to +24 dbm a verification of the channel masks has to be done. If the mask requirements aren't met, a reduction of the data rate and/or frequency deviation is necessary. For the low-power radio stations the masks printed in Figure 8, 10, 12, 14, and 16 are defined. Figure 8 defines the channel mask of a radio channel whose frequency is from MHz to MHz. In this case the maximum permitted output power is 1 mw (0 dbm), so the measurement is performed with this output power level. Figure 9 shows the SPIRIT1 Doc ID Rev 1 11/35

12 Transmitter AN4133 compliance with the mask, the measurement is performed with the center frequency set to MHz. Figure 10 defines the channel mask of a radio channel whose frequency is from MHz to MHz. The max output power permitted for this bandwidth is 20 mw (+13 dbm), the SPIRIT1 doesn't support this output power, so the mask compliance is verified with an output power of 10 dbm. In Figure 11 the SPIRIT1 compliance mask is shown. The output power is set to 7 dbm to enter on the mask. To work with a higher output power, a reduction of the data rate and/or frequency deviation is necessary. The center frequency is set to MHz. Figure 12 and 14 define the channel masks of a radio channel whose frequency is from MHz to MHz. The compliance mask measurements are shown respectively in Figure 13 and15. The measurements are performed with the center frequency set to 928 MHz and 925 MHz respectively. The mask in Figure 16 is defined for maximum permitted output power of 1 mw (0 dbm) of a radio channel whose frequency is from MHz to MHz. The measurement is performed with SPIRIT1 set to provide this output power level. Figure 17 shows the compliance with the mask. The measurement is performed with the center frequency set to 929 MHz. 12/35 Doc ID Rev 1

13 Transmitter Figure 4. Convenience radio station channel mask of a radio channel whose frequency is from MHz to MHz Unit: dbm/100khz 200 khz (200 x n) khz 200 khz Power at the edge: +4 dbm or less Spurious emission strength (920.3 MHz to MHz) -29 dbm/100 khz 0-10 Adjacent channel leakagepower: -5 dbm or less Lower adjacent unit channel f c (Center frequency) Upper adjacent unit channel Unit: khz f c 0-100x(n-1) f c x(n-1) Figure Convenience radio station channel mask of a radio channel at 922 MHz Convenience radio station 10 dbm MHz to MHz bandwidth ARIB Mask E E E E E E E E E E E+08 Doc ID Rev 1 13/35

14 Transmitter AN4133 Figure 6. Convenience radio station channel mask of a radio channel whose frequency is from MHz to MHz Unit: dbm/100khz 200 khz (200 x n) khz 200 khz Spurious emission strength (920.3 MHz to MHz) -29 dbm/100 khz 0-10 Adjacent channel leakage power: -5 dbm or less Lower adjacent unit channel f c (Center frequency) Upper adjacent unit channel Unit: khz f c -100xn f c +100xn Figure 7. Convenience radio station channel mask of a radio channel at 923 MHz Convenience radio station 10 dbm MHz to MHz bandwidth ARIB Mask E E E E E E E E E E E+08 14/35 Doc ID Rev 1

15 Transmitter Figure 8. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz Unit: dbm/100khz Power at the edge: dbm or less 200 khz (200 x n) khz 200 khz 0-10 Spurious emission strength (915 MHz to 930 MHz) -36 dbm/100 khz Adjacent channel leakagepower: -26 dbm or less Lower adjacent unit channel f c (Center frequency) Upper adjacent unit channel Unit: khz f c 0-100x(n-1) f c x(n-1) Figure 9. Low-power radio station channel mask of a radio channel at MHz Low-power radio station 0 dbm MHz to MHz bandwidth 10 0 ARIB Mask E E E E E E E E E E E+08 Doc ID Rev 1 15/35

16 Transmitter AN4133 Figure 10. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz Power at the edge: -7 dbm or less Unit: dbm/100khz khz (200 x n) khz 200 khz 0-10 Spurious emission strength (920.3 MHz to MHz) -36 dbm/100 khz Adjacent channel leakage power: -15 dbm or less (If the case of 1 mw or less, -26 dbm or less) Lower adjacent unit channel f c 0-100x(n-1) f c (Center frequency) Upper adjacent unit channel f c x(n-1) Unit: khz Figure 11. Low-power radio station channel mask of a radio channel at MHz Low-power radio station 7 dbm MHz to MHz bandwidth ARIB Mask E E E E E E E E E E E+08 16/35 Doc ID Rev 1

17 Transmitter Figure 12. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz (antenna power is 1 mw or less)l Unit: dbm/100khz 200 khz (200 x n) khz 200 khz 0-10 Spurious emission strength (915 MHz to 930 MHz) -36 dbm/100 khz Adjacent channel leakage power: -26 dbm or less Lower adjacent unit channel f c (Center frequency) Upper adjacent unit channel Unit: khz f c -100xn f c +100xn Figure 13. Low-power radio station channel mask of a radio channel at 928 MHz 10 Low-power radio station 0 dbm MHz to MHz bandwidth 0 ARIB Mask E E E E E E E E E E E+08 Doc ID Rev 1 17/35

18 Transmitter AN4133 Figure 14. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz (antenna power is more than 1 mw and 20 mw or less) Unit: dbm/100khz 200 khz (200 x n) khz 200 khz Spurious emission strength (915 MHz to 930 MHz) -36 dbm/100 khz Adjacent channel leakage power: -15 dbm or less Lower adjacent unit channel f c (Center frequency) Upper adjacent unit channel Unit: khz f c -100xn f c +100xn Figure 15. Low-power radio station channel mask of a radio channel at 925 MHz Low-power radio station 10 dbm MHz to MHz bandwidth ARIB Mask E E E E E E E E E E E+08 18/35 Doc ID Rev 1

19 Transmitter Figure 16. Low-power radio station channel mask of a radio channel whose frequency is from MHz to MHz Unit: dbm/100khz 100 khz (100 x n) khz 100 khz 0-10 Spurious emission strength (915 MHz to 930 MHz) -36 dbm/100 khz Adjacent channel leakage power: -26 dbm or less Lower adjacent unit channel f c (Center frequency) Upper adjacent unit channel Unit: khz f c xn f c +50xn Figure 17. Low-power radio station channel mask of a radio channel at 929 MHz 10 0 Low-power radio station 0 dbm MHz to MHz bandwidth ARIB Mask E E E E E E E E E E E+08 Doc ID Rev 1 19/35

20 Permissible values for unwanted emission intensity AN Permissible values for unwanted emission intensity Unwanted emissions in the spurious domain are emissions at a frequency other than those of the desired carrier frequency and its sidebands associated with normal test modulation. The spurious emission strength at the antenna input has to be less than the values in Table 1 for the convenience radio stations and Table 3 for the low-power radio station. The measurements for the convenience radio station are done with the carrier set to 922 MHz. The measurements for the low-power radio station are done with the carrier set to MHz. The measurements performed for the convenience radio station are given in Figure 18 to 26 which show that all requirements are met. Special attention must be given to the requirement in the to MHz band. In this band the levels of the spurious have to be lower than -55 dbm on 100 khz band without considering the channel occupied bandwidth. This value is in obvious contradiction with the value reported in the convenience radio station channel masks (Figure 4 and 6) where for the same spurious a maximum level of -29 dbm integrated in 100 khz bandwidth is given. In Figure 22 the two different masks are shown and it is clear that the second requirement is much less stringent than the first one. The measurements performed for the low-power radio station are given in Figure 27 to 33. For the low-power case the full requirements are met. Figure 18. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission MHz 1.00E E E E E E E E+08 20/35 Doc ID Rev 1

21 Permissible values for unwanted emission intensity Figure 19. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission MHz 7.10E E E E E E E E E E+08 Figure 20. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission MHz E E E E E E E E+08 Doc ID Rev 1 21/35

22 Permissible values for unwanted emission intensity AN4133 Figure 21. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission MHz E E E E E E+08 Figure 22. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission MHz ARIB table E E E E E E E E E+08 22/35 Doc ID Rev 1

23 Permissible values for unwanted emission intensity Figure 23. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission MHz E E E E E E+08 Figure 24. Convenience radio station emission in the MHz bandwidth Convenience radio station spurious emission 930 MHz - 1 GHz E E E E E E E+08 Doc ID Rev 1 23/35

24 Permissible values for unwanted emission intensity AN4133 Figure 25. Convenience radio station emission in the GHz bandwidth Convenience radio station spurious emission GHz E E E E E+09 Figure 26. Convenience radio station emission in the Hz bandwidth Convenience radio station spurious emission GHz 1.22E E E E E+09 24/35 Doc ID Rev 1

25 Permissible values for unwanted emission intensity Figure 27. Low-power radio station emission in the MHz bandwidth Low-power radio station spurious emission MHz E E E E E E E E+08 Figure 28. Low-power radio station emission in the MHz bandwidth Low-power radio station spurious emission MHz 7.10E E E E E E E E E E+08 Doc ID Rev 1 25/35

26 Permissible values for unwanted emission intensity AN4133 Figure 29. Low-power radio station emission in the MHz bandwidth Low-power radio station spurious emission MHz E E E E E E E E+08 Figure 30. Low-power radio station emission in the MHz bandwidth 10 0 Low-power radio station spurious emission MHz E E E E E E+08 26/35 Doc ID Rev 1

27 Permissible values for unwanted emission intensity Figure 31. Low-power radio station emission in the MHz bandwidth Low-power radio station spurious emission 930 MHz - 1 GHz E E E E E E E+08 Figure 32. Low-power radio station emission in the GHz bandwidth Low-power radio station spurious emission GHz 1.00E E E E E+09 Doc ID Rev 1 27/35

28 Permissible values for unwanted emission intensity AN4133 Figure 33. Low-power radio station emission in the GHz bandwidth Low-power radio station spurious emission GHz 1.22E E E E E+09 28/35 Doc ID Rev 1

29 Receiver 5 Receiver Only one measurement is required for the receiver, the limit on secondary radiated emission. This measurement is performed under the following conditions: Tc = 25 C, Vdd = 3.0 V, f = 922 MHz (middle frequency of the bandwidth used). 5.1 Limit on secondary radiated emission Spurious radiation from the receiver includes components at any frequency, radiated by the equipment. The spurious emission strength at the antenna input has to be less than the values in Table 2 for the convenience radio stations and Table 4 for the low-power radio stations. The two tables are the same, so the measurement is performed only once, setting the receiver to 922 MHz, maximum gain. The measurement results are given in Figure 34 to 39. The entire standard requirements are met from the SPIRIT1 in receiver mode. Figure 34. Receiver radiated emission in the MHz bandwidth Convenience radio station receiver spurious emission MHz E E E E E E E E+08 Doc ID Rev 1 29/35

30 Receiver AN4133 Figure 35. Receiver radiated emission in the MHz bandwidth Convenience radio station receiver spurious emission MHz E E E E E E E E E E+08 Figure 36. Receiver radiated emission in the MHz bandwidth Convenience radio station receiver spurious emission MHz E E E E E E E E+08 30/35 Doc ID Rev 1

31 Receiver Figure 37. Receiver radiated emission in the MHz bandwidth Convenience radio station receiver spurious emission MHz E E E E E E E E+08 Figure 38. Receiver radiated emission in the MHz bandwidth Convenience radio station receiver spurious emission 930 MHz - 1 GHz E E E E E E E+08 Doc ID Rev 1 31/35

32 Receiver AN4133 Figure 39. Receiver radiated emission in the 1-6 GHz bandwidth Convenience radio station receiver spurious emission 1-6 GHz E E E E E E+09 32/35 Doc ID Rev 1

33 References 6 References 1. SPIRIT1 datasheet 2. ARIB STD-T108: "920 MHz band telemeter, telecontrol and data transmission radio equipment" Doc ID Rev 1 33/35

34 Revision history AN Revision history Table 5. Document revision history Date Revision Changes 12-Jul12 1 Initial release. 34/35 Doc ID Rev 1

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