SLAS564 Data sheet

SLAS564H August 2007 – July 2024 CDCE937 , CDCEL937

PRODUCTION DATA

Package Options

Mechanical Data (Package|Pins)

PW|20
- MPDS362A

Thermal pad, mechanical data (Package|Pins)

PW|20
- QFND419A

Orderable Information

8.1 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 CDCEx937. 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 8-1 SDA and SCL Registers

ADDRESS OFFSET	REGISTER DESCRIPTION	TABLE
00h	Generic Configuration Register	Table 8-3
10h	PLL1 Configuration Register	Table 8-4
20h	PLL2 Configuration Register	Table 8-5
30h	PLL3 Configuration Register	Table 8-6

The gray-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 8-2 Configuration Register, External Control Terminals

				Y1	PLL1 SETTINGS			PLL2 SETTINGS			PLL3 SETTINGS
	EXTERNAL CONTROL PINS			OUTPUT SELECTION	FREQ. SELECTION	SSC SELECTION	OUTPUT SELECTION	FREQ. SELECTION	SSC SELECTION	OUTPUT SELECTION	FREQ. SELECTION	SSC SELECTION	OUTPUT SELECTION
	S2	S1	S0	Y1	FS1	SSC1	Y2Y3	FS2	SSC2	Y4Y5	FS3	SSC3	Y6Y7
0	0	0	0	Y1_0	FS1_0	SSC1_0	Y2Y3_0	FS2_0	SSC2_0	Y4Y5_0	FS3_0	SSC3_0	Y6Y7_0
1	0	0	1	Y1_1	FS1_1	SSC1_1	Y2Y3_1	FS2_1	SSC2_1	Y4Y5_1	FS3_1	SSC3_1	Y6Y7_1
2	0	1	0	Y1_2	FS1_2	SSC1_2	Y2Y3_2	FS2_2	SSC2_2	Y4Y5_2	FS3_2	SSC3_2	Y6Y7_2
3	0	1	1	Y1_3	FS1_3	SSC1_3	Y2Y3_3	FS2_3	SSC2_3	Y4Y5_3	FS3_3	SSC3_3	Y6Y7_3
4	1	0	0	Y1_4	FS1_4	SSC1_4	Y2Y3_4	FS2_4	SSC2_4	Y4Y5_4	FS3_4	SSC3_4	Y6Y7_4
5	1	0	1	Y1_5	FS1_5	SSC1_5	Y2Y3_5	FS2_5	SSC2_5	Y4Y5_5	FS3_5	SSC3_5	Y6Y7_5
6	1	1	0	Y1_6	FS1_6	SSC1_6	Y2Y3_6	FS2_6	SSC2_6	Y4Y5_6	FS3_6	SSC3_6	Y6Y7_6
7	1	1	1	Y1_7	FS1_7	SSC1_7	Y2Y3_7	FS2_7	SSC2_7	Y4Y5_7	FS3_7	SSC3_7	Y6Y7_7
	Address Offset⁽¹⁾			04h	13h	10h–12h	15h	23h	20h–22h	25h	33h	30h–32h	35h

(1) Address Offset refers to the byte address in the Configuration Register in the following pages.

Table 8-3 Generic Configuration Register

OFFSET⁽¹⁾	BIT⁽²⁾	ACRONYM	DEFAULT⁽³⁾	DESCRIPTION
00h	7	E_EL	Xb	Device identification (read-only): 1 is CDCE937 (3.3 V), 0 is CDCEL937 (1.8 V)
	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 Status:⁽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.
	4	PWDN	0b		0 – device active (PLL1 and all outputs are enabled) 1 – device power down (PLL1 in power down and all outputs in 3-state)
	3:2	INCLK	00b	Input clock selection:		00 – Xtal 01 – VCXO 10 – LVCMOS 11 – reserved
	1:0	SLAVE_ADR	00b	Programmable 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 pin 18/19⁽⁶⁾
	6	SPICON	0b		0 – serial programming interface SDA (pin 19) and SCL (pin 18) 1 – control pins S1 (pin 19) and S2 (pin 18)
	5:4	Y1_ST1	11b	Y1-State0/1 Definition
	3:2	Y1_ST0	01b		00 – device power down (all PLLs in power down and all outputs in 3-State) 01 – Y1 disabled to 3-state			10 – Y1 disabled to low 11 – Y1 enabled
	1:0	Pdiv1 [9:8]	2h	10-Bit Y1-Output-Divider Pdiv1:			0 – divider reset and stand-by 1-to-1023 – divider value
03h	7:0	Pdiv1 [7:0]	2h	10-Bit Y1-Output-Divider Pdiv1:			0 – divider reset and stand-by 1-to-1023 – divider value
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_5	0b
	4	Y1_4	0b
	3	Y1_3	0b
	2	Y1_2	0b
	1	Y1_1	1b
	0	Y1_0	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
05h	2:0		0b	Reserved – do not write other than 0
06h	7:1	BCOUNT	40h	7-Bit Byte Count (defines the number of bytes which is sent from this device at the next Block Read transfer); all bytes have to be read out to correctly finish the read cycle.)
06h	0	EEWRITE	0b	Initiate EEPROM Write Cycle⁽⁴⁾ ⁽⁹⁾		0– no EEPROM write cycle 1 – start EEPROM write cycle (internal configuration register is saved to the EEPROM)
07h-0Fh		—	0h	Unused address range

(1) Writing data beyond ‘40h’ can affect device function.

(2) All data transferred with the MSB first.

(3) Unless customer-specific setting.

(4) During EEPROM programming, no data is allowed to be sent to the device through the SDA/SCL bus until the programming sequence is completed. However, data can be read out during the programming sequence (Byte Read or Block Read).

(5) If this bit is set to high in the EEPROM, the actual data in the EEPROM is permanently locked. There is no further programming possible. However, data can still be written through the SDA/SCL bus to the internal register to change device function on the fly. New data can no longer be saved to the EEPROM. EELOCK is effective only if written into the EEPROM.

(6) 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 V_DDOUT 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.

(7) 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.

(8) The internal load capacitor (C1, C2) has to be used to achieve the best clock performance. External capacitors must be used only to finely adjust C_L by a few pFs. The value of C_L can be programmed with a resolution of 1 pF for a crystal load range of 0 pF to 20 pF. For C_L > 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 C_L. For more information about VCXO configuration and crystal recommendation, see VCXO Application Guideline for CDCE(L)9xx Family (SCAA085).

(9) Note: The EEPROM WRITE bit must be sent last. This verifies 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 has to 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 8-4 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]	000b
	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]	000b
	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 – f_{VCO1_0} (predefined by PLL1_0 – Multiplier/Divider value) 1 – f_{VCO1_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	0b	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 3-State (PLL1 is in power down) 01 – Y2/Y3 disabled to 3-State 10–Y2/Y3 disabled to low 11 – Y2/Y3 enabled
	1:0	Y2Y3_ST0	01b	Y2, Y3-State0/1definition:
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
16h	6:0	Pdiv2	08h	7-Bit Y2-Output-Divider Pdiv2:			0 – reset and stand-by 1-to-127 is divider value
17h	7	—	0b	Reserved – do not write others than 0
17h	6:0	Pdiv3	04h	7-Bit Y3-Output-Divider Pdiv3:			0 – reset and stand-by 1-to-127 is divider value
18h	7:0	PLL1_0N [11:4]	E10h	PLL1_0⁽⁵⁾: 30-Bit Multiplier/Divider value for frequency f_{VCO1_0} (for more information, see PLL Frequency Planning).
19h	7:4	PLL1_0N [3:0]	E10h
19h	3:0	PLL1_0R [8:5]	132h
1Ah	7:3	PLL1_0R[4:0]	132h
1Ah	2:0	PLL1_0Q [5:3]	1Dh
1Bh	7:5	PLL1_0Q [2:0]	1Dh
	4:2	PLL1_0P [2:0]	010b
	1:0	VCO1_0_RANGE	11b	f_{VCO1_0} range selection:			00 – f_{VCO1_0} < 125 MHz 01 – 125 MHz ≤ f_{VCO1_0} < 150 MHz 10 – 150 MHz ≤ f_{VCO1_0} < 175 MHz 11 – f_{VCO1_0} ≥ 175 MHz
1Ch	7:0	PLL1_1N [11:4]	E10h	PLL1_1⁽⁵⁾: 30-Bit Multiplier/Divider value for frequency f_{VCO1_1} (for more information see PLL Frequency Planning).
1Dh	7:4	PLL1_1N [3:0]	E10h
1Dh	3:0	PLL1_1R [8:5]	132h
1Eh	7:3	PLL1_1R[4:0]	132h
1Eh	2:0	PLL1_1Q [5:3]	1Dh
1Fh	7:5	PLL1_1Q [2:0]	1Dh
	4:2	PLL1_1P [2:0]	010b
	1:0	VCO1_1_RANGE	00b	f_{VCO1_1} range selection:			00 – f_{VCO1_1} < 125 MHz 01 – 125 MHz ≤ f_{VCO1_1} < 150 MHz 10 – 150 MHz ≤ f_{VCO1_1} < 175 MHz 11 – f_{VCO1_1} ≥ 175 MHz

(1) Writing data beyond 40h can adversely affect device function.

(2) All data is transferred MSB-first.

(3) Unless a custom setting is used.

(4) 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.

(5) PLL settings limits: 16 ≤ q ≤ 63, 0 ≤ p ≤ 7, 0 ≤ r ≤ 511, 0 < N < 4096.

Table 8-5 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]	000b
	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]	000b
	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 – f_{VCO2_0} (predefined by PLL2_0 – Multiplier/Divider value) 1 – f_{VCO2_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	0b	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 3-State (PLL2 is in power down) 01 – Y4/Y5 disabled to 3-State 10–Y4/Y5 disabled to low 11 – Y4/Y5 enabled
	1:0	Y4Y5_ST0	01b	Y4, Y5-State0/1definition:
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
26h	6:0	Pdiv4	05h	7-Bit Y4-Output-Divider Pdiv4:			0 – reset and stand-by 1-to-127 – divider value
27h	7	—	0b	Reserved – do not write others than 0
27h	6:0	Pdiv5	05h	7-Bit Y5-Output-Divider Pdiv5:			0 – reset and stand-by 1-to-127 – divider value
28h	7:0	PLL2_0N [11:4	E58h	PLL2_0⁽⁵⁾: 30-Bit Multiplier/Divider value for frequency f_{VCO2_0} (for more information see PLL Frequency Planning).
29h	7:4	PLL2_0N [3:0]	E58h
29h	3:0	PLL2_0R [8:5]	198h
2Ah	7:3	PLL2_0R[4:0]	198h
2Ah	2:0	PLL2_0Q [5:3]	1Ch
2Bh	7:5	PLL2_0Q [2:0]	1Ch
	4:2	PLL2_0P [2:0]	010b
	1:0	VCO2_0_RANGE	11b	f_{VCO2_0} range selection:			00 – f_{VCO2_0} < 125 MHz 01 – 125 MHz ≤ f_{VCO2_0} < 150 MHz 10 – 150 MHz ≤ f_{VCO2_0} < 175 MHz 11 – f_{VCO2_0} ≥ 175 MHz
2Ch	7:0	PLL2_1N [11:4]	E58h	PLL2_1⁽⁵⁾: 30-Bit Multiplier/Divider value for frequency f_{VCO2_1} (for more information see PLL Frequency Planning).
2Dh	7:4	PLL2_1N [3:0]	E58h
2Dh	3:0	PLL2_1R [8:5]	198h
2Eh	7:3	PLL2_1R[4:0]	198h
2Eh	2:0	PLL2_1Q [5:3]	1Ch
2Fh	7:5	PLL2_1Q [2:0]	1Ch
	4:2	PLL2_1P [2:0]	010b
	1:0	VCO2_1_RANGE	00b	f_{VCO2_1} range selection:			00 – f_{VCO2_1} < 125 MHz 01 – 125 MHz ≤ f_{VCO2_1} < 150 MHz 10 – 150 MHz ≤ f_{VCO2_1} < 175 MHz 11 – f_{VCO2_1} ≥ 175 MHz

(1) Writing data beyond 40h can adversely affect device function.

(2) All data is transferred MSB-first.

(3) Unless a custom setting is used.

(4) 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.

(5) PLL settings limits: 16 ≤ q ≤ 63, 0 ≤ p ≤ 7, 0 ≤ r ≤ 511, 0 < N < 4096.

Table 8-6 PLL3 Configuration Register

OFFSET⁽¹⁾	BIT⁽²⁾	ACRONYM	DEFAULT⁽³⁾	DESCRIPTION
30h	7:5	SSC3_7 [2:0]	000b	SSC3: PLL3 SSC Selection (Modulation Amount)⁽⁴⁾
	4:2	SSC3_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	SSC3_5 [2:1]	000b
31h	7	SSC3_5 [0]	000b
	6:4	SSC3_4 [2:0]	000b
	3:1	SSC3_3 [2:0]	000b
	0	SSC3_2 [2]	000b
32h	7:6	SSC3_2 [1:0]	000b
	5:3	SSC3_1 [2:0]	000b
	2:0	SSC3_0 [2:0]	000b
33h	7	FS3_7	0b	FS3_x: PLL3 Frequency Selection⁽⁴⁾
	6	FS3_6	0b		0 – f_{VCO3_0} (predefined by PLL3_0 – Multiplier/Divider value) 1 – f_{VCO3_1} (predefined by PLL3_1 – Multiplier/Divider value)
	5	FS3_5	0b
	4	FS3_4	0b
	3	FS3_3	0b
	2	FS3_2	0b
	1	FS3_1	0b
	0	FS3_0	0b
34h	7	MUX3	0b	PLL3 Multiplexer:		0 – PLL3 1 – PLL3 Bypass (PLL3 is in power down)
	6	M6	1b	Output Y6 Multiplexer:		0 – Pdiv4 1 – Pdiv6
	5:4	M7	10b	Output Y7 Multiplexer:		00 – Pdiv4-Divider 01 – Pdiv6-Divider 10 – Pdiv7-Divider 11 – reserved
	3:2	Y6Y7_ST1	11b	Y6, Y7-State0/1definition:		00 – Y6/Y7 disabled to 3-State and PLL3 power down 01 – Y6/Y7 disabled to 3-State 10 –Y6/Y7 disabled to low 11 – Y6/Y7 enabled
	1:0	Y6Y7_ST0	01b	Y6, Y7-State0/1definition:
35h	7	Y6Y7_7	0b	Y6Y7_x Output State Selection⁽⁴⁾
	6	Y6Y7_6	0b		0 – state0 (predefined by Y6Y7_ST0) 1 – state1 (predefined by Y6Y7_ST1)
	5	Y6Y7_5	0b
	4	Y6Y7_4	0b
	3	Y6Y7_3	0b
	2	Y6Y7_2	0b
	1	Y6Y7_1	1b
	0	Y6Y7_0	0b
36h	7	SSC3DC	0b	PLL3 SSC down/center selection:			0 – down 1 – center
36h	6:0	Pdiv6	09h	7-Bit Y6-Output-Divider Pdiv6:			0 – reset and stand-by 1-to-127 – divider value
37h	7	—	0b	Reserved – do not write others than 0
37h	6:0	Pdiv7	04h	7-Bit Y7-Output-Divider Pdiv7:			0 – reset and stand-by 1-to-127 – divider value
38h	7:0	PLL3_0N [11:4]	FF8h	PLL3_0⁽⁵⁾: 30-Bit Multiplier/Divider value for frequency f_{VCO3_0} (for more information, see PLL Frequency Planning).
39h	7:4	PLL3_0N [3:0]	FF8h
39h	3:0	PLL3_0R [8:5]	000h
3Ah	7:3	PLL3_0R[4:0]	000h
3Ah	2:0	PLL3_0Q [5:3]	10h
3Bh	7:5	PLL3_0Q [2:0]	10h
	4:2	PLL3_0P [2:0]	001b
	1:0	VCO3_0_RANGE	11b	f_{VCO3_0} range selection:			00 – f_{VCO3_0} < 125 MHz 01 – 125 MHz ≤ f_{VCO3_0} < 150 MHz 10 – 150 MHz ≤ f_{VCO3_0} < 175 MHz 11 – f_{VCO3_0} ≥ 175 MHz
3Ch	7:0	PLL3_1N [11:4]	FF8h	PLL3_1⁽⁵⁾: 30-Bit Multiplier/Divider value for frequency f_{VCO3_1} (for more information, see PLL Frequency Planning).
3Dh	7:4	PLL3_1N [3:0]	FF8h
3Dh	3:0	PLL3_1R [8:5]	000h
3Eh	7:3	PLL3_1R[4:0]	000h
3Eh	2:0	PLL3_1Q [5:3]	10h
3Fh	7:5	PLL3_1Q [2:0]	10h
	4:2	PLL3_1P [2:0]	001b
	1:0	VCO3_1_RANGE	00b	f_{VCO3_1} range selection:			00 – f_{VCO3_1} < 125 MHz 01 – 125 MHz ≤ f_{VCO3_1} < 150 MHz 10 – 150 MHz ≤ f_{VCO3_1} < 175 MHz 11 – f_{VCO3_1} ≥ 175 MHz

(1) Writing data beyond 40h can affect device function.

(2) All data is transferred MSB-first.

(3) Unless a custom setting is used.

(4) These are the bits of the Control Terminal Register. The user can pre-define up to eight different control settings. At normal device operation, these setting can be selected by the external control pins, S0, S1, and S2.

(5) PLL settings limits: 16 ≤ q ≤ 63, 0 ≤ p ≤ 7, 0 ≤ r ≤ 511, 0 < N < 4096.