SCAS847I July   2007  – October 2016 CDCE925 , CDCEL925

PRODUCTION DATA.  

  1. Features
  2. Applications
  3. Description
  4. Revision History
  5. Description (continued)
  6. Pin Configuration and Functions
  7. Specifications
    1. 7.1 Absolute Maximum Ratings
    2. 7.2 ESD Ratings
    3. 7.3 Recommended Operating Conditions
    4. 7.4 Thermal Information
    5. 7.5 Electrical Characteristics
    6. 7.6 EEPROM Specification
    7. 7.7 Timing Requirements: CLK_IN
    8. 7.8 Timing Requirements: SDA/SCL
    9. 7.9 Typical Characteristics
  8. Parameter Measurement Information
  9. Detailed Description
    1. 9.1 Overview
    2. 9.2 Functional Block Diagram
    3. 9.3 Feature Description
      1. 9.3.1 Control Terminal Setting
      2. 9.3.2 Default Device Setting
      3. 9.3.3 SDA/SCL Serial Interface
      4. 9.3.4 Data Protocol
    4. 9.4 Device Functional Modes
      1. 9.4.1 SDA/SCL Hardware Interface
    5. 9.5 Programming
    6. 9.6 Register Maps
      1. 9.6.1 SDA/SCL Configuration Registers
  10. 10Application and Implementation
    1. 10.1 Application Information
    2. 10.2 Typical Application
      1. 10.2.1 Design Requirements
      2. 10.2.2 Detailed Design Procedure
        1. 10.2.2.1 Spread Spectrum Clock (SSC)
        2. 10.2.2.2 PLL Multiplier/Divider Definition
        3. 10.2.2.3 Crystal Oscillator Start-Up
        4. 10.2.2.4 Frequency Adjustment With Crystal Oscillator Pulling
        5. 10.2.2.5 Unused Inputs and Outputs
        6. 10.2.2.6 Switching Between XO and VCXO Mode
      3. 10.2.3 Application Curves
  11. 11Power Supply Recommendations
  12. 12Layout
    1. 12.1 Layout Guidelines
    2. 12.2 Layout Example
  13. 13Device and Documentation Support
    1. 13.1 Device Support
      1. 13.1.1 Third-Party Products Disclaimer
      2. 13.1.2 Development Support
    2. 13.2 Documentation Support
      1. 13.2.1 Related Documentation
    3. 13.3 Related Links
    4. 13.4 Receiving Notification of Documentation Updates
    5. 13.5 Community Resources
    6. 13.6 Trademarks
    7. 13.7 Electrostatic Discharge Caution
    8. 13.8 Glossary
  14. 14Mechanical, Packaging, and Orderable Information

封装选项

机械数据 (封装 | 引脚)
散热焊盘机械数据 (封装 | 引脚)
订购信息

Detailed Description

Overview

The CDCE925 and CDCEL925 devices are modular PLL-based, low-cost, high-performance, programmable clock synthesizers, multipliers, and dividers. They generate up to five output clocks from a single input frequency. Each output can be programmed in-system for any clock frequency up to 230 MHz, using one of the two integrated configurable PLLs.

The CDCx925 has separate output supply pins, VDDOUT, which is 1.8 V for CDCEL925 and 2.5 V to 3.3 V for CDCE925.

The input accepts an external crystal or LVCMOS clock signal. If an external crystal is used, an on-chip load capacitor is adequate for most applications. The value of the load capacitor is programmable from 0 pF to 20 pF. Additionally, a selectable on-chip VCXO allows synchronization of the output frequency to an external control signal, that is, the PWM signal.

The deep M/N divider ratio allows the generation of 0-ppm audio and video, networking (WLAN, Bluetooth, Ethernet, GPS), or interface (USB, IEEE1394, memory stick) clocks from a reference input frequency such as
27 MHz.

All PLLs support spread-spectrum clocking (SSC). SSC can be center-spread or down-spread clocking. This is a common technique to reduce electro-magnetic interference (EMI).

Based on the PLL frequency and the divider settings, the internal loop filter components are automatically adjusted to achieve high stability, and to optimize the jitter-transfer characteristic of each PLL.

The device supports non-volatile EEPROM programming for easy customization of the device in the application. It is preset to a factory default configuration (see Default Device Setting). It can be reprogrammed to a different application configuration before PCB assembly, or reprogrammed by in-system programming. All device settings are programmable through the SDA and SCL bus, a 2-wire serial interface.

Three free programmable control inputs, S0, S1, and S2, can be used to control various aspects of operation including frequency selection, changing the SSC parameters to lower EMI, PLL bypass, power down, or other control features like outputs disable to low, outputs in high-impedance state, and so forth.

The CDCx925 operates in a 1.8-V environment. It operates within a temperature range of –40°C to 85°C.

Functional Block Diagram

CDCE925 CDCEL925 fbd_cas847.gif
Figure 6. Functional Block Diagram for CDCEx925

Feature Description

Control Terminal Setting

The CDCEx925 has three user-definable control terminals (S0, S1, and S2) which allow external control of device settings. They can be programmed to any of the following settings:

  • Spread spectrum clocking selection → spread type and spread amount selection
  • Frequency selection → switching between any of two user-defined frequencies
  • Output state selection → output configuration and power-down control

The user can predefine up to eight different control settings. Table 1 and Table 2 explain these settings.

Table 1. Control Terminal Definition

EXTERNAL
CONTROL
BITS
PLL1 SETTING PLL2 SETTING Y1 SETTING
Control function PLL frequency selection SSC selection Output Y2/Y3 selection PLL frequency selection SSC selection Output Y4/Y5 selection Output Y1 and power-down selection

Table 2. PLL Setting (Can Be Selected for Each PLL Individual)(1)

SSC SELECTION (CENTER/DOWN)
SSCx [3-Bits] CENTER DOWN
0 0 0 0% (off) 0% (off)
0 0 1 ±0.25% –0.25%
0 1 0 ±0.5% –0.5%
0 1 1 ±0.75% –0.75%
1 0 0 ±1% –1.0%
1 0 1 ±1.25% –1.25%
1 1 0 ±1.5% –1.5%
1 1 1 ±2% –2%
FREQUENCY SELECTION(2)
FSx FUNCTION
0 Frequency0
1 Frequency1
OUTPUT SELECTION(3) (Y2 ... Y5)
YxYx FUNCTION
0 State0
1 State1
Center/down-spread, Frequency0/1 and State0/1 are user-definable in the PLLx configuration register.
Frequency0 and Frequency1 can be any frequency within the specified fVCO range.
State0/1 selection is valid for both outputs of the corresponding PLL module and can be power down, high-impedance state, low, or active

Table 3. Y1 Setting(1)

Y1 SELECTION
Y1 FUNCTION
0 State 0
1 State 1
State0 and State1 are user definable in the generic configuration register and can be power down, high-impedance state, low, or active.

SDA/S1 and SCL/S2 pins of the CDCEx925 are dual-function pins. In the default configuration, they are predefined as the SDA/SCL serial programming interface. They can be programmed to control pins (S1/S2) by setting the relevant bits in the EEPROM. Note that the changes of the bits in the control register (bit [6] of byte 02h) have no effect until they are written into the EEPROM.

Once they are set as control pins, the serial programming interface is no longer available. However, if VDDOUT is forced to GND, the two control pins, S1 and S2, temporally act as serial programming pins (SDA/SCL).

S0 is not a multi-use pin; it is a control pin only.

Default Device Setting

The internal EEPROM of CDCEx925 is preconfigured as shown in Figure 7. The input frequency is passed through the output as a default. This allows the device to operate in default mode without the extra production step of programming it. The default setting appears after power is supplied or after a power-down/up sequence until it is reprogrammed by the user to a different application configuration. A new register setting is programmed through the serial SDA/SCL interface.

CDCE925 CDCEL925 default_cas847.gif Figure 7. Preconfiguration of CDCEx925 Internal EEPROM

Table 4 shows the factory default setting for the control terminal register (external control pins). Note that even though eight different register settings are possible, in default configuration, only the first two settings (0 and 1) can be selected with S0, as S1 and S2 are configured as programming pins in the default mode.

Table 4. Factory Default Settings for Control Terminal Register(1)

Y1 PLL1 SETTINGS PLL2 SETTINGS
EXTERNAL CONTROL PINS OUTPUT SELECTION FREQUENCY SELECTION SSC SELECTION OUTPUT SELECTION FREQUENCY SELECTION SSC SELECTION OUTPUT SELECTION
S2 S1 S0 Y1 FS1 SSC1 Y2Y3 FS2 SSC2 Y4Y5
SCL (I2C) SDA (I2C) 0 High-impedance state fVCO1_0 Off High-impedance state fVCO2_0 Off High-impedance state
SCL (I2C) SDA (I2C) 1 Enabled fVCO1_0 Off Enabled fVCO2_0 Off Enabled
S1 is SDA and S2 is SCL in default mode or when programmed (SPICON bit 6 of register 2 set to 0). They do not have any control-pin function but they are internally interpreted as if S1 = 0 and S2 = 0. S0, however, is a control pin which in the default mode switches all outputs ON or OFF (as previously predefined).

SDA/SCL Serial Interface

This section describes the SDA/SCL interface of the CDCEx925 device. The CDCEx925 operates as a slave device of the 2-wire serial SDA/SCL bus, compatible with the popular SMBus or I2C specification. It operates in the standard-mode transfer (up to 100 kbps) and fast-mode transfer (up to 400 kbps) and supports 7-bit addressing.

The SDA/S1 and SCL/S2 pins of the CDCEx925 are dual-function pins. In the default configuration they are used as SDA/SCL serial programming interface. They can be reprogrammed as general-purpose control pins, S1 and S2, by changing the corresponding EEPROM setting, byte 02h, bit [6].

CDCE925 CDCEL925 tim_dia_cas847.gif Figure 8. Timing Diagram for SDA/SCL Serial Control Interface

Data Protocol

The device supports Byte Write and Byte Read and Block Write and Block Read operations.

For Byte Write/Read operations, the system controller can individually access addressed bytes.

For Block Write/Read operations, the bytes are accessed in sequential order from lowest to highest byte (with most-significant bit first) with the ability to stop after any complete byte has been transferred. The numbers of bytes read out are defined by byte count in the generic configuration register. At the Block Read instruction, all bytes defined in the byte count must be read out to finish the read cycle correctly.

Once a byte has been sent, it is written into the internal register and is effective immediately. This applies to each transferred byte regardless of whether this is a Byte Write or a Block Write sequence.

If the EEPROM write cycle is initiated, the internal SDA registers are written into the EEPROM. During this write cycle, data is not accepted at the SDA/SCL bus until the write cycle is completed. However, data can be read out during the programming sequence (Byte Read or Block Read). The programming status can be monitored by EEPIP, byte 01h–bit 6.

The offset of the indexed byte is encoded in the command code, as described in Table 5.

Table 5. Slave Receiver Address (7 Bits)

DEVICE A6 A5 A4 A3 A2 A1(1) A0(1) R/W
CDCEx913 1 1 0 0 1 0 1 1/0
CDCEx925 1 1 0 0 1 0 0 1/0
CDCEx925 1 1 0 1 1 0 1 1/0
CDCEx949 1 1 0 1 1 0 0 1/0
Address bits A0 and A1 are programmable through the SDA/SCL bus (byte 01, bit [1:0]. This allows addressing up to four devices connected to the same SDA/SCL bus. The least-significant bit of the address byte designates a write or read operation.

Device Functional Modes

SDA/SCL Hardware Interface

Figure 9 shows how the CDCEx925 clock synthesizer is connected to the SDA/SCL serial interface bus. Multiple devices can be connected to the bus, but the speed may need to be reduced (400 kHz is the maximum) if many devices are connected.

Note that the pullup resistors (RP) depend on the supply voltage, bus capacitance, and number of connected devices. The recommended pullup value is 4.7 kΩ. It must meet the minimum sink current of 3 mA at VOLmax = 0.4 V for the output stages (for more details, see SMBus or I2C Bus specification).

CDCE925 CDCEL925 hardware_if_cas847.gif Figure 9. SDA/SCL Hardware Interface

Programming

Table 6. Command Code Definition

BIT DESCRIPTION
7 0 = Block Read or Block Write operation
1 = Byte Read or Byte Write operation
(6:0) Byte offset for Byte Read, Block Read, Byte Write and Block Write operations.
CDCE925 CDCEL925 prog_seq_cas847.gif Figure 10. Generic Programming Sequence
CDCE925 CDCEL925 byte_wr_cas847.gif Figure 11. Byte Write Protocol
CDCE925 CDCEL925 byte_rd_cas847.gif Figure 12. Byte Read Protocol
CDCE925 CDCEL925 block_wr_cas847.gif
Data byte 0 bits [7:0] is reserved for Revision Code and Vendor Identification. Also, it is used for internal test purpose and must not be overwritten.
Figure 13. Block Write Protocol
CDCE925 CDCEL925 block_rd_cas847.gif Figure 14. Block Read Protocol

Register Maps

SDA/SCL Configuration Registers

The clock input, control pins, PLLs, and output stages are user configurable. The following tables and explanations describe the programmable functions of the CDCEx925. All settings can be manually written into the device through the SDA/SCL bus or easily programmed by using the TI Pro-Clock™ software. TI Pro-Clock software allows the user to quickly make all settings and automatically calculates the values for optimized performance at lowest jitter.

Table 7. SDA/SCL Registers

ADDRESS OFFSET REGISTER DESCRIPTION TABLE
00h Generic configuration register Table 9
10h PLL1 configuration register Table 10
20h PLL2 configuration register Table 11

The grey-highlighted bits, described in the Configuration Registers tables in the following pages, belong to the Control Terminal Register. The user can predefine up to eight different control settings. These settings then can be selected by the external control pins, S0, S1, and S2 (see Control Terminal Setting).

Table 8. Configuration Register, External Control Terminals

Y1 PLL1 SETTINGS PLL2 SETTINGS
EXTERNAL CONTROL PINS OUTPUT
SELECTION
FREQUENCY
SELECTION
SSC SELECTION OUTPUT
SELECTION
FREQUENCY
SELECTION
SSC SELECTION OUTPUT
SELECTION
S2 S1 S0 Y1 FS1 SSC1 Y2Y3 FS2 SSC2 Y4Y5
0 0 0 0 Y1_0 FS1_0 SSC1_0 Y2Y3_0 FS2_0 SSC2_0 Y4Y5_0
1 0 0 1 Y1_1 FS1_1 SSC1_1 Y2Y3_1 FS2_1 SSC2_1 Y4Y5_1
2 0 1 0 Y1_2 FS1_2 SSC1_2 Y2Y3_2 FS2_2 SSC2_2 Y4Y5_2
3 0 1 1 Y1_3 FS1_3 SSC1_3 Y2Y3_3 FS2_3 SSC2_3 Y4Y5_3
4 1 0 0 Y1_4 FS1_4 SSC1_4 Y2Y3_4 FS2_4 SSC2_4 Y4Y5_4
5 1 0 1 Y1_5 FS1_5 SSC1_5 Y2Y3_5 FS2_5 SSC2_5 Y4Y5_5
6 1 1 0 Y1_6 FS1_6 SSC1_6 Y2Y3_6 FS2_6 SSC2_6 Y4Y5_6
7 1 1 1 Y1_7 FS1_7 SSC1_7 Y2Y3_7 FS2_7 SSC2_7 Y4Y5_7
Address offset(1) 04h 13h 10h–12h 15h 23h 20h–22h 25h
Address offset refers to the byte address in the configuration register in Table 9, Table 10, and Table 11.

Table 9. Generic Configuration Register

OFFSET(1) BIT(2) ACRONYM DEFAULT(3) DESCRIPTION
00h 7 E_EL Xb Device identification (read-only): 1 is CDCE925 (3.3 V out), 0 is CDCEL925 (1.8 V out)
6:4 RID Xb Revision identification number (read-only)
3:0 VID 1h Vendor identification number (read-only)
01h 7 0b Reserved – always write 0
6 EEPIP 0b EEPROM programming Status4:(4) (read-only) 0 – EEPROM programming is completed
1 – EEPROM is in programming mode
5 EELOCK 0b Permanently lock EEPROM data(5) 0 – EEPROM is not locked
1 – EEPROM is permanently locked
4 PWDN 0b Device power down (overwrites S0/S1/S2 setting; configuration register settings are unchanged)
Note: PWDN cannot be set to 1 in the EEPROM.
0 – Device active (all PLLs and all outputs are enabled)
1 – Device power down (all PLLs in power down and all outputs in high-impedance state)
3:2 INCLK 00b Input clock selection: 00 – Xtal  01 – VCXO   10 – LVCMOS 1 – Reserved
1:0 SLAVE_ADR 00b Address bits A0 and A1 of the slave receiver address
02h 7 M1 1b Clock source selection for output Y1: 0 – Input clock  1 – PLL1 clock
6 SPICON 0b Operation mode selection for pins 14/15(6)
0 – Serial programming interface SDA (pin 15) and SCL (pin 14)
1 – Control pins S1 (pin 15) and S2 (pin 14)
5:4 Y1_ST1 11b Y1-State0/1 definition00 – Device power down (all PLLs in power down and all outputs in high-impedance state)

01 – Y1 disabled to high-impedance state 10 – Y1 disabled to low
11 – Y1 enabled
3:2 Y1_ST0 01b
1:0 Pdiv1 [9:8] 001h 10-bit Y1-Output-Divider Pdiv1: 0 – Divider is reset and in standby
1 to 1023 – Divider value
03h 7:0 Pdiv1 [7:0]
04h 7 Y1_7 0b Y1_ST0/Y1_ST1 State Selection(7)
6 Y1_6 0b 0 – State0 (predefined by Y1_ST0)
1 – State1 (predefined by Y1_ST1)
5 Y1_6 0b
4 Y1_6 0b
3 Y1_6 0b
2 Y1_6 0b
1 Y1_6 0b
0 Y1_6 0b
05h 7:3 XCSEL 0Ah Crystal load-capacitor selection(8) 00h – 0 pF
01h – 1 pF
02h – 2 pF
  :
14h to 1Fh – 20 pF
CDCE925 CDCEL925 table_sch_cas844.gif
2:0 0b Reserved – do not write other than 0.
06h 7:1 BCOUNT 30h 7-bit byte count (defines the number of bytes which is sent from this device at the next Block Read transfer); all bytes must be read out to correctly finish the read cycle.
0 EEWRITE 0b Initiate EEPROM write cycle(9) 0 – No EEPROM write cycle
1 – Start EEPROM write cycle (internal registers are saved to the EEPROM)
07h-0Fh 0h Reserved – do not write other than 0
Writing data beyond 30h may affect device function.
All data transferred with the MSB first
Unless customer-specific setting
During EEPROM programming, no data is allowed to be sent to the device through the SDA/SCL bus until the programming sequence is completed. Data, however, can be read out during the programming sequence (Byte Read or Block Read).
If this bit is set to high in the EEPROM, the actual data in the EEPROM is permanently locked. No further programming is possible. Data, however can still be written through the SDA/SCL bus to the internal register to change device function on the fly. But new data can no longer be saved to the EEPROM. EELOCK is effective only if written into the EEPROM.
Selection of control pins is effective only if written into the EEPROM. Once written into the EEPROM, the serial programming pins are no longer available. However, if VDDOUT is forced to GND, the two control pins, S1 and S2, temporally act as serial programming pins (SDA/SCL), and the two slave receiver address bits are reset to A0 = 0 and A1 = 0.
These are the bits of the control terminal register. The user can predefine up to eight different control settings. These settings then can be selected by the external control pins, S0, S1, and S2.
The internal load capacitor (C1, C2) must be used to achieve the best clock performance. External capacitors must be used only to finely adjust CL by a few picofarads. The value of CL can be programmed with a resolution of 1 pF for a crystal load range of 0 pF to 20 pF. For CL > 20 pF, use additional external capacitors. Also, the value of the device input capacitance has to be considered which always adds 1.5 pF (6 pF/2 pF) to the selected CL. For more information about VCXO configuration and crystal recommendation, see VCXO Application Guideline for CDCE(L)9xx Family (SCAA085).
Note: The EEPROM WRITE bit must be sent last. This ensures that the content of all internal registers are stored in the EEPROM. The EEWRITE cycle is initiated with the rising edge of the EEWRITE bit. A static level-high does not trigger an EEPROM WRITE cycle. The EEWRITE bit must be reset to low after the programming is completed. The programming status can be monitored by reading out EEPIP. If EELOCK is set to high, no EEPROM programming is possible.

Table 10. PLL1 Configuration Register

OFFSET(1) BIT(2) ACRONYM DEFAULT(3) DESCRIPTION
10h 7:5 SSC1_7 [2:0] 000b SSC1: PLL1 SSC selection (modulation amount). (4)
4:2 SSC1_6 [2:0] 000b Down
000 (Off)
001 – 0.25%
010 – 0.5%
011 – 0.75%
100 – 1.0%
101 – 1.25%
110 – 1.5%
111 – 2.0%
Center
000 (Off)
001 ± 0.25%
010 ± 0.5%
011 ± 0.75%
100 ± 1.0%
101 ± 1.25%
110 ± 1.5%
111 ± 2.0%
1:0 SSC1_5 [2:1] 000b
11h 7 SSC1_5 [0]
6:4 SSC1_4 [2:0] 000b
3:1 SSC1_3 [2:0] 000b
0 SSC1_2 [2] 000b
12h 7:6 SSC1_2 [1:0]
5:3 SSC1_1 [2:0] 000b
2:0 SSC1_0 [2:0] 000b
13h 7 FS1_7 0b FS1_x: PLL1 frequency selection(4)
6 FS1_6 0b 0 – fVCO1_0 (predefined by PLL1_0 – multiplier/divider value)
1 – fVCO1_1 (predefined by PLL1_1 – multiplier/divider value)
5 FS1_5 0b
4 FS1_4 0b
3 FS1_3 0b
2 FS1_2 0b
1 FS1_1 0b
0 FS1_0 0b
14h 7 MUX1 1b PLL1 multiplexer: 0 – PLL1
1 – PLL1 bypass (PLL1 is in power down)
6 M2 1b Output Y2 multiplexer: 0 – Pdiv1
1 – Pdiv2
5:4 M3 10b Output Y3 multiplexer: 00 – Pdiv1-divider
01 – Pdiv2-divider
10 – Pdiv3-divider
11 – Reserved
3:2 Y2Y3_ST1 11b Y2, Y3-state0/1definition: 00 – Y2/Y3 disabled to high-impedance state (PLL1 is in power down)
01 – Y2/Y3 disabled to high-impedance state (PLL1 on)
10 – Y2/Y3 disabled to low (PLL1 on)
11 – Y2/Y3 enabled (normal operation, PLL1 on)
1:0 Y2Y3_ST0 01b
15h 7 Y2Y3_7 0b Y2Y3_x output state selection(4)
6 Y2Y3_6 0b 0 – state0 (predefined by Y2Y3_ST0)
1 – state1 (predefined by Y2Y3_ST1)
5 Y2Y3_5 0b
4 Y2Y3_4 0b
3 Y2Y3_3 0b
2 Y2Y3_2 0b
1 Y2Y3_1 1b
0 Y2Y3_0 0b
16h 7 SSC1DC 0b PLL1 SSC down/center selection: 0 – Down
1 – Center
6:0 Pdiv2 01h 7-bit Y2-output-divider Pdiv2: 0 – Reset and in standby
1 to 127 – Divider value
17h 7 0b Reserved – do not write others than 0
6:0 Pdiv3 01h 7-bit Y3-output-divider Pdiv3: 0 – Reset and in standby
1 to 127 – Divider value
18h 7:0 PLL1_0N [11:4 004h PLL1_0(5): 30-bit multiplier/divider value for frequency fVCO1_0
(for more information, see PLL Multiplier/Divider Definition).
19h 7:4 PLL1_0N [3:0]
3:0 PLL1_0R [8:5] 000h
1Ah 7:3 PLL1_0R[4:0]
2:0 PLL1_0Q [5:3] 10h
1Bh 7:5 PLL1_0Q [2:0]
4:2 PLL1_0P [2:0] 010b
1:0 VCO1_0_RANGE 00b fVCO1_0 range selection: 00 – fVCO1_0 < 125 MHz
01 – 125 MHz ≤ fVCO1_0 < 150 MHz
10 – 150 MHz ≤ fVCO1_0 < 175 MHz
11 – fVCO1_0 ≥ 175 MHz
1Ch 7:0 PLL1_1N [11:4] 004h PLL1_1(5): 30-bit multiplier/divider value for frequency fVCO1_1
(for more information, see PLL Multiplier/Divider Definition).
1Dh 7:4 PLL1_1N [3:0]
3:0 PLL1_1R [8:5] 000h
1Eh 7:3 PLL1_1R[4:0]
2:0 PLL1_1Q [5:3] 10h
1Fh 7:5 PLL1_1Q [2:0]
4:2 PLL1_1P [2:0] 010b
1:0 VCO1_1_RANGE 00b fVCO1_1 range selection: 00 – fVCO1_1 < 125 MHz
01 – 125 MHz ≤ fVCO1_1 < 150 MHz
10 – 150 MHz ≤ fVCO1_1 < 175 MHz
11 – fVCO1_1 ≥ 175 MHz
Writing data beyond 30h may adversely affect device function.
All data is transferred MSB-first.
Unless a custom setting is used
The user can predefine up to eight different control settings. In normal device operation, these settings can be selected by the external control pins, S0, S1, and S2.
PLL settings limits: 16 ≤ q ≤ 63, 0 ≤ p ≤ 7, 0 ≤ r ≤ 511, 0 < N < 4096

Table 11. PLL2 Configuration Register

OFFSET(1) BIT(2) ACRONYM DEFAULT(3) DESCRIPTION
20h 7:5 SSC2_7 [2:0] 000b SSC2: PLL2 SSC selection (modulation amount). (4)
4:2 SSC2_6 [2:0] 000b Down
000 (Off)
001 – 0.25%
010 – 0.5%
011 – 0.75%
100 – 1.0%
101 – 1.25%
110 – 1.5%
111 – 2.0%
Center
000 (Off)
001 ± 0.25%
010 ± 0.5%
011 ± 0.75%
100 ± 1.0%
101 ± 1.25%
110 ± 1.5%
111 ± 2.0%
1:0 SSC2_5 [2:1] 000b
21h 7 SSC2_5 [0]
6:4 SSC2_4 [2:0] 000b
3:1 SSC2_3 [2:0] 000b
0 SSC2_2 [2] 000b
22h 7:6 SSC2_2 [1:0]
5:3 SSC2_1 [2:0] 000b
2:0 SSC2_0 [2:0] 000b
23h 7 FS2_7 0b FS2_x: PLL2 frequency selection(4)
6 FS2_6 0b 0 – fVCO2_0 (predefined by PLL2_0 – multiplier/divider value)
1 – fVCO2_1 (predefined by PLL2_1 – multiplier/divider value)
5 FS2_5 0b
4 FS2_4 0b
3 FS2_3 0b
2 FS2_2 0b
1 FS2_1 0b
0 FS2_0 0b
24h 7 MUX2 1b PLL2 multiplexer: 0 – PLL2
1 – PLL2 bypass (PLL2 is in power down)
6 M4 1b Output Y4 multiplexer: 0 – Pdiv2
1 – Pdiv4
5:4 M5 10b Output Y5 multiplexer: 00 – Pdiv2-divider
01 – Pdiv4-divider
10 – Pdiv5-divider
11 – Reserved
3:2 Y4Y5_ST1 11b Y4, Y5-State0/1definition: 00 – Y4/Y5 disabled to high-impedance state (PLL2 is in power down)
01 – Y4/Y5 disabled to high-impedance state (PLL2 on)
10–Y4/Y5 disabled to low (PLL2 on)
11 – Y4/Y5 enabled (normal operation, PLL2 on)
1:0 Y4Y5_ST0 01b
25h 7 Y4Y5_7 0b Y4Y5_x output state selection(4)
6 Y4Y5_6 0b 0 – state0 (predefined by Y4Y5_ST0)
1 – state1 (predefined by Y4Y5_ST1)
5 Y4Y5_5 0b
4 Y4Y5_4 0b
3 Y4Y5_3 0b
2 Y4Y5_2 0b
1 Y4Y5_1 1b
0 Y4Y5_0 0b
26h 7 SSC2DC 0b PLL2 SSC down/center selection: 0 – Down
1 – Center
6:0 Pdiv4 01h 7-Bit Y4-output-divider Pdiv4: 0 – Reset and in standby
1 to 127 – Divider value
27h 7 0b Reserved – do not write others than 0
6:0 Pdiv5 01h 7-bit Y5-output-divider Pdiv5: 0 – Reset and in standby
1 to 127 – Divider value
28h 7:0 PLL2_0N [11:4 004h PLL2_0(5): 30-Bit Multiplier/Divider value for frequency fVCO2_0
(for more information, see PLL Multiplier/Divider Definition).
29h 7:4 PLL2_0N [3:0]
3:0 PLL2_0R [8:5] 000h
2Ah 7:3 PLL2_0R[4:0]
2:0 PLL2_0Q [5:3] 10h
2Bh 7:5 PLL2_0Q [2:0]
4:2 PLL2_0P [2:0] 010b
1:0 VCO2_0_RANGE 00b fVCO2_0 range selection: 00 – fVCO2_0 < 125 MHz
01 – 125 MHz ≤ fVCO2_0 < 150 MHz
10 – 150 MHz ≤ fVCO2_0 < 175 MHz
11 – fVCO2_0 ≥ 175 MHz
2Ch 7:0 PLL2_1N [11:4] 004h PLL2_1(5): 30-bit multiplier/divider value for frequency fVCO2_1
(for more information, see PLL Multiplier/Divider Definition).
2Dh 7:4 PLL2_1N [3:0]
3:0 PLL2_1R [8:5] 000h
2Eh 7:3 PLL2_1R[4:0]
2:0 PLL2_1Q [5:3] 10h
2Fh 7:5 PLL2_1Q [2:0]
4:2 PLL2_1P [2:0] 010b
1:0 VCO2_1_RANGE 00b fVCO2_1 range selection: 00 – fVCO2_1 < 125 MHz
01 – 125 MHz ≤ fVCO2_1 < 150 MHz
10 – 150 MHz ≤ fVCO2_1 < 175 MHz
11 – fVCO2_1 ≥ 175 MHz
Writing data beyond 30h may adversely affect device function.
All data is transferred MSB-first.
Unless a custom setting is used
The user can predefine up to eight different control settings. In normal device operation, these settings can be selected by the external control pins, S0, S1, and S2.
PLL settings limits: 16 ≤ q ≤ 63, 0 ≤ p ≤ 7, 0 ≤ r ≤ 511, 0 < N < 4096