diff --git a/go.mod b/go.mod
index f9de51b5..a8582894 100644
--- a/go.mod
+++ b/go.mod
@@ -5,5 +5,6 @@ go 1.16
 require (
 	github.com/bwesterb/go-ristretto v1.2.2
 	golang.org/x/crypto v0.0.0-20220722155217-630584e8d5aa
+	golang.org/x/sync v0.0.0-20220722155255-886fb9371eb4 // indirect
 	golang.org/x/sys v0.0.0-20220728004956-3c1f35247d10
 )
diff --git a/go.sum b/go.sum
index c04d9236..b086edf9 100644
--- a/go.sum
+++ b/go.sum
@@ -3,6 +3,8 @@ github.com/bwesterb/go-ristretto v1.2.2/go.mod h1:fUIoIZaG73pV5biE2Blr2xEzDoMj7N
 golang.org/x/crypto v0.0.0-20220722155217-630584e8d5aa h1:zuSxTR4o9y82ebqCUJYNGJbGPo6sKVl54f/TVDObg1c=
 golang.org/x/crypto v0.0.0-20220722155217-630584e8d5aa/go.mod h1:IxCIyHEi3zRg3s0A5j5BB6A9Jmi73HwBIUl50j+osU4=
 golang.org/x/net v0.0.0-20211112202133-69e39bad7dc2/go.mod h1:9nx3DQGgdP8bBQD5qxJ1jj9UTztislL4KSBs9R2vV5Y=
+golang.org/x/sync v0.0.0-20220722155255-886fb9371eb4 h1:uVc8UZUe6tr40fFVnUP5Oj+veunVezqYl9z7DYw9xzw=
+golang.org/x/sync v0.0.0-20220722155255-886fb9371eb4/go.mod h1:RxMgew5VJxzue5/jJTE5uejpjVlOe/izrB70Jof72aM=
 golang.org/x/sys v0.0.0-20201119102817-f84b799fce68/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
 golang.org/x/sys v0.0.0-20210423082822-04245dca01da/go.mod h1:h1NjWce9XRLGQEsW7wpKNCjG9DtNlClVuFLEZdDNbEs=
 golang.org/x/sys v0.0.0-20210615035016-665e8c7367d1/go.mod h1:oPkhp1MJrh7nUepCBck5+mAzfO9JrbApNNgaTdGDITg=
diff --git a/ot/simot/simot_test.go b/ot/simot/simot_test.go
new file mode 100644
index 00000000..32e4aa55
--- /dev/null
+++ b/ot/simot/simot_test.go
@@ -0,0 +1,231 @@
+// Reference: https://eprint.iacr.org/2015/267.pdf (1 out of 2 OT case)
+// Sender has 2 messages m0, m1
+// Receiver receives mc based on the choice bit c
+
+package simot
+
+import (
+	"bytes"
+	"crypto/rand"
+	"testing"
+
+	"github.com/cloudflare/circl/group"
+)
+
+const testSimOTCount = 100
+
+func simOT(myGroup group.Group, sender *SenderSimOT, receiver *ReceiverSimOT, m0, m1 []byte, choice, index int) error {
+	// Initialization
+	A := sender.InitSender(myGroup, m0, m1, index)
+
+	// Round 1
+	// Sender sends A to receiver
+	B := receiver.Round1Receiver(myGroup, choice, index, A)
+
+	// Round 2
+	// Receiver sends B to sender
+	e0, e1 := sender.Round2Sender(B)
+
+	// Round 3
+	// Sender sends e0 e1 to receiver
+	errDec := receiver.Round3Receiver(e0, e1, receiver.c)
+	if errDec != nil {
+		return errDec
+	}
+
+	return nil
+}
+
+func testNegativeSimOT(t *testing.T, myGroup group.Group, choice int) {
+	var sender SenderSimOT
+	var receiver ReceiverSimOT
+	m0 := make([]byte, myGroup.Params().ScalarLength)
+	m1 := make([]byte, myGroup.Params().ScalarLength)
+	_, errRand := rand.Read(m0)
+	if errRand != nil {
+		panic(errRand)
+	}
+	_, errRand = rand.Read(m1)
+	if errRand != nil {
+		panic(errRand)
+	}
+
+	// Initialization
+	A := sender.InitSender(myGroup, m0, m1, 0)
+
+	// Round 1
+	B := receiver.Round1Receiver(myGroup, choice, 0, A)
+
+	// Round 2
+	e0, e1 := sender.Round2Sender(B)
+	// Round 3
+
+	// Here we pass in the flipped choice bit, to prove the decryption will fail
+	// The receiver will not learn anything about m_{1-c}
+	errDec := receiver.Round3Receiver(e0, e1, 1-choice)
+	if errDec == nil {
+		t.Error("SimOT decryption failed", errDec)
+	}
+
+	if choice == 0 {
+		equal0 := bytes.Compare(sender.m0, receiver.mc)
+		if equal0 == 0 {
+			t.Error("Receiver decryption should fail")
+		}
+		equal1 := bytes.Compare(sender.m1, receiver.mc)
+		if equal1 == 0 {
+			t.Error("Receiver decryption should fail")
+		}
+	} else {
+		equal0 := bytes.Compare(sender.m0, receiver.mc)
+		if equal0 == 0 {
+			t.Error("Receiver decryption should fail")
+		}
+		equal1 := bytes.Compare(sender.m1, receiver.mc)
+		if equal1 == 0 {
+			t.Error("Receiver decryption should fail")
+		}
+	}
+}
+
+// Input: myGroup, the group we operate in
+func testSimOT(t *testing.T, myGroup group.Group, choice int) {
+	var sender SenderSimOT
+	var receiver ReceiverSimOT
+
+	m0 := make([]byte, myGroup.Params().ScalarLength)
+	m1 := make([]byte, myGroup.Params().ScalarLength)
+	_, errRand := rand.Read(m0)
+	if errRand != nil {
+		panic(errRand)
+	}
+	_, errRand = rand.Read(m1)
+	if errRand != nil {
+		panic(errRand)
+	}
+
+	errDec := simOT(myGroup, &sender, &receiver, m0, m1, choice, 0)
+	if errDec != nil {
+		t.Error("AES GCM Decryption failed")
+	}
+
+	if choice == 0 {
+		equal0 := bytes.Compare(sender.m0, receiver.mc)
+		if equal0 != 0 {
+			t.Error("Receiver decryption failed")
+		}
+	} else {
+		equal1 := bytes.Compare(sender.m1, receiver.mc)
+		if equal1 != 0 {
+			t.Error("Receiver decryption failed")
+		}
+	}
+}
+
+func benchmarSimOT(b *testing.B, myGroup group.Group) {
+	var sender SenderSimOT
+	var receiver ReceiverSimOT
+	m0 := make([]byte, myGroup.Params().ScalarLength)
+	m1 := make([]byte, myGroup.Params().ScalarLength)
+	_, errRand := rand.Read(m0)
+	if errRand != nil {
+		panic(errRand)
+	}
+	_, errRand = rand.Read(m1)
+	if errRand != nil {
+		panic(errRand)
+	}
+
+	for iter := 0; iter < b.N; iter++ {
+		errDec := simOT(myGroup, &sender, &receiver, m0, m1, iter%2, 0)
+		if errDec != nil {
+			b.Error("AES GCM Decryption failed")
+		}
+	}
+}
+
+func benchmarkSimOTRound(b *testing.B, myGroup group.Group) {
+	var sender SenderSimOT
+	var receiver ReceiverSimOT
+	m0 := make([]byte, myGroup.Params().ScalarLength)
+	m1 := make([]byte, myGroup.Params().ScalarLength)
+	_, errRand := rand.Read(m0)
+	if errRand != nil {
+		panic(errRand)
+	}
+	_, errRand = rand.Read(m1)
+	if errRand != nil {
+		panic(errRand)
+	}
+
+	b.Run("Sender-Initialization", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			sender.InitSender(myGroup, m0, m1, 0)
+		}
+	})
+
+	A := sender.InitSender(myGroup, m0, m1, 0)
+
+	b.Run("Receiver-Round1", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			receiver.Round1Receiver(myGroup, 0, 0, A)
+		}
+	})
+
+	B := receiver.Round1Receiver(myGroup, 0, 0, A)
+
+	b.Run("Sender-Round2", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			sender.Round2Sender(B)
+		}
+	})
+
+	e0, e1 := sender.Round2Sender(B)
+
+	b.Run("Receiver-Round3", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			errDec := receiver.Round3Receiver(e0, e1, receiver.c)
+			if errDec != nil {
+				b.Error("Receiver-Round3 decryption failed")
+			}
+		}
+	})
+
+	errDec := receiver.Round3Receiver(e0, e1, receiver.c)
+	if errDec != nil {
+		b.Error("Receiver-Round3 decryption failed")
+	}
+
+	// Confirm
+	equal0 := bytes.Compare(sender.m0, receiver.mc)
+	if equal0 != 0 {
+		b.Error("Receiver decryption failed")
+	}
+}
+
+func TestSimOT(t *testing.T) {
+	t.Run("SimOT", func(t *testing.T) {
+		for i := 0; i < testSimOTCount; i++ {
+			currGroup := group.P256
+			choice := i % 2
+			testSimOT(t, currGroup, choice)
+		}
+	})
+	t.Run("SimOTNegative", func(t *testing.T) {
+		for i := 0; i < testSimOTCount; i++ {
+			currGroup := group.P256
+			choice := i % 2
+			testNegativeSimOT(t, currGroup, choice)
+		}
+	})
+}
+
+func BenchmarkSimOT(b *testing.B) {
+	currGroup := group.P256
+	benchmarSimOT(b, currGroup)
+}
+
+func BenchmarkSimOTRound(b *testing.B) {
+	currGroup := group.P256
+	benchmarkSimOTRound(b, currGroup)
+}
diff --git a/ot/simot/simotlocal.go b/ot/simot/simotlocal.go
new file mode 100644
index 00000000..fabd3de5
--- /dev/null
+++ b/ot/simot/simotlocal.go
@@ -0,0 +1,240 @@
+package simot
+
+import (
+	"crypto/aes"
+	"crypto/cipher"
+	"crypto/rand"
+	"crypto/subtle"
+	"errors"
+	"io"
+
+	"github.com/cloudflare/circl/group"
+	"golang.org/x/crypto/sha3"
+)
+
+const keyLength = 16
+
+// AES GCM encryption, we don't need to pad because our input is fixed length
+// Need to use authenticated encryption to defend against tampering on ciphertext
+// Input: key, plaintext message
+// Output: ciphertext
+func aesEncGCM(key, plaintext []byte) []byte {
+	block, err := aes.NewCipher(key)
+	if err != nil {
+		panic(err)
+	}
+
+	aesgcm, err := cipher.NewGCM(block)
+	if err != nil {
+		panic(err.Error())
+	}
+
+	nonce := make([]byte, aesgcm.NonceSize())
+	if _, err := io.ReadFull(rand.Reader, nonce); err != nil {
+		panic(err)
+	}
+
+	ciphertext := aesgcm.Seal(nonce, nonce, plaintext, nil)
+	return ciphertext
+}
+
+// AES GCM decryption
+// Input: key, ciphertext message
+// Output: plaintext
+func aesDecGCM(key, ciphertext []byte) ([]byte, error) {
+	block, err := aes.NewCipher(key)
+	if err != nil {
+		panic(err)
+	}
+	aesgcm, err := cipher.NewGCM(block)
+	if err != nil {
+		panic(err.Error())
+	}
+	nonceSize := aesgcm.NonceSize()
+	if len(ciphertext) < nonceSize {
+		return nil, errors.New("ciphertext too short")
+	}
+
+	nonce, encryptedMessage := ciphertext[:nonceSize], ciphertext[nonceSize:]
+
+	plaintext, err := aesgcm.Open(nil, nonce, encryptedMessage, nil)
+
+	return plaintext, err
+}
+
+// Initialization
+
+// Input: myGroup, the group we operate in
+// Input: m0, m1 the 2 message of the sender
+// Input: index, the index of this SimOT
+// Output: A = [a]G, a the sender randomness
+func (sender *SenderSimOT) InitSender(myGroup group.Group, m0, m1 []byte, index int) group.Element {
+	sender.a = myGroup.RandomNonZeroScalar(rand.Reader)
+	sender.k0 = make([]byte, keyLength)
+	sender.k1 = make([]byte, keyLength)
+	sender.m0 = m0
+	sender.m1 = m1
+	sender.index = index
+	sender.A = myGroup.NewElement()
+	sender.A.MulGen(sender.a)
+	sender.myGroup = myGroup
+	return sender.A.Copy()
+}
+
+// Round 1
+
+// ---- sender should send A to receiver ----
+
+// Input: myGroup, the group we operate in
+// Input: choice, the receiver choice bit
+// Input: index, the index of this SimOT
+// Input: A, from sender
+// Output: B = [b]G if c == 0, B = A+[b]G if c == 1 (Implementation in constant time). b, the receiver randomness
+func (receiver *ReceiverSimOT) Round1Receiver(myGroup group.Group, choice int, index int, A group.Element) group.Element {
+	receiver.b = myGroup.RandomNonZeroScalar(rand.Reader)
+	receiver.c = choice
+	receiver.kR = make([]byte, keyLength)
+	receiver.index = index
+	receiver.A = A
+	receiver.myGroup = myGroup
+
+	bG := myGroup.NewElement()
+	bG.MulGen(receiver.b)
+	cScalar := myGroup.NewScalar()
+	cScalar.SetUint64(uint64(receiver.c))
+	add := receiver.A.Copy()
+	add.Mul(receiver.A, cScalar)
+	receiver.B = myGroup.NewElement()
+	receiver.B.Add(bG, add)
+
+	return receiver.B.Copy()
+}
+
+// Round 2
+
+// ---- receiver should send B to sender ----
+
+// Input: B from the receiver
+// Output: e0, e1, encryption of m0 and m1 under key k0, k1
+func (sender *SenderSimOT) Round2Sender(B group.Element) ([]byte, []byte) {
+	sender.B = B
+
+	aB := sender.myGroup.NewElement()
+	aB.Mul(sender.B, sender.a)
+	maA := sender.myGroup.NewElement()
+	maA.Mul(sender.A, sender.a)
+	maA.Neg(maA)
+	aBaA := sender.myGroup.NewElement()
+	aBaA.Add(aB, maA)
+
+	// Hash the whole transcript A|B|...
+	AByte, errByte := sender.A.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	BByte, errByte := sender.B.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	aBByte, errByte := aB.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	hashByte0 := append(AByte, BByte...)
+	hashByte0 = append(hashByte0, aBByte...)
+
+	s := sha3.NewShake128()
+	_, errWrite := s.Write(hashByte0)
+	if errWrite != nil {
+		panic(errWrite)
+	}
+	_, errRead := s.Read(sender.k0)
+	if errRead != nil {
+		panic(errRead)
+	}
+
+	aBaAByte, errByte := aBaA.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	hashByte1 := append(AByte, BByte...)
+	hashByte1 = append(hashByte1, aBaAByte...)
+	s = sha3.NewShake128()
+	_, errWrite = s.Write(hashByte1)
+	if errWrite != nil {
+		panic(errWrite)
+	}
+	_, errRead = s.Read(sender.k1)
+	if errRead != nil {
+		panic(errRead)
+	}
+
+	e0 := aesEncGCM(sender.k0, sender.m0)
+	sender.e0 = e0
+
+	e1 := aesEncGCM(sender.k1, sender.m1)
+	sender.e1 = e1
+
+	return sender.e0, sender.e1
+}
+
+// Round 3
+
+// ---- sender should send e0, e1 to receiver ----
+
+// Input: e0, e1: encryption of m0 and m1 from the sender
+// Input: choice, choice bit of receiver
+// Choose e0 or e1 based on choice bit in constant time
+func (receiver *ReceiverSimOT) Round3Receiver(e0, e1 []byte, choice int) error {
+	receiver.ec = make([]byte, len(e1))
+	// If c == 1, copy e1
+	subtle.ConstantTimeCopy(choice, receiver.ec, e1)
+	// If c == 0, copy e0
+	subtle.ConstantTimeCopy(1-choice, receiver.ec, e0)
+
+	AByte, errByte := receiver.A.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	BByte, errByte := receiver.B.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	bA := receiver.myGroup.NewElement()
+	bA.Mul(receiver.A, receiver.b)
+	bAByte, errByte := bA.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	// Hash the whole transcript so far
+	hashByte := append(AByte, BByte...)
+	hashByte = append(hashByte, bAByte...)
+
+	s := sha3.NewShake128()
+	_, errWrite := s.Write(hashByte)
+	if errWrite != nil {
+		panic(errWrite)
+	}
+	_, errRead := s.Read(receiver.kR) // kR, decryption key of mc
+	if errRead != nil {
+		panic(errRead)
+	}
+	mc, errDec := aesDecGCM(receiver.kR, receiver.ec)
+	if errDec != nil {
+		return errDec
+	}
+	receiver.mc = mc
+	return nil
+}
+
+func (receiver *ReceiverSimOT) Returnmc() []byte {
+	return receiver.mc
+}
+
+func (sender *SenderSimOT) Returne0e1() ([]byte, []byte) {
+	return sender.e0, sender.e1
+}
+
+func (sender *SenderSimOT) Returnm0m1() ([]byte, []byte) {
+	return sender.m0, sender.m1
+}
diff --git a/ot/simot/simotparty.go b/ot/simot/simotparty.go
new file mode 100644
index 00000000..d4f67713
--- /dev/null
+++ b/ot/simot/simotparty.go
@@ -0,0 +1,29 @@
+package simot
+
+import "github.com/cloudflare/circl/group"
+
+type SenderSimOT struct {
+	index   int           // Indicate which OT
+	m0      []byte        // The M0 message from sender
+	m1      []byte        // The M1 message from sender
+	a       group.Scalar  // The randomness of the sender
+	A       group.Element // [a]G
+	B       group.Element // The random group element from the receiver
+	k0      []byte        // The encryption key of M0
+	k1      []byte        // The encryption key of M1
+	e0      []byte        // The encryption of M0 under k0
+	e1      []byte        // The encryption of M1 under k1
+	myGroup group.Group   // The elliptic curve we operate in
+}
+
+type ReceiverSimOT struct {
+	index   int           // Indicate which OT
+	c       int           // The choice bit of the receiver
+	A       group.Element // The random group element from the sender
+	b       group.Scalar  // The randomness of the receiver
+	B       group.Element // B = [b]G if c == 0, B = A+[b]G if c == 1
+	kR      []byte        // The decryption key of receiver
+	ec      []byte        // The encryption of mc
+	mc      []byte        // The decrypted message from sender
+	myGroup group.Group   // The elliptic curve we operate in
+}
diff --git a/tss/ecdsa/dkls/fmul/fmulLocal.go b/tss/ecdsa/dkls/fmul/fmulLocal.go
new file mode 100644
index 00000000..0ad7d13a
--- /dev/null
+++ b/tss/ecdsa/dkls/fmul/fmulLocal.go
@@ -0,0 +1,242 @@
+package fmul
+
+import (
+	"crypto/rand"
+	"math/big"
+	"sync"
+
+	"github.com/cloudflare/circl/group"
+	"github.com/cloudflare/circl/ot/simot"
+	"golang.org/x/sync/errgroup"
+)
+
+// Input: myGroup, the group we operate in
+// Input: securityParameter
+// Output: The number of SimOT needed
+func DecideNumOT(myGroup group.Group, sp int) int {
+	numSimOT := int(myGroup.Params().ScalarLength*8) + sp
+	return numSimOT
+}
+
+// ---- Sender Initialization ----
+
+// Input: myGroup, the group we operate in
+// Input: a, the sender private input
+// Input: n, the total number of SimOT
+// Output: Array of A=[ai]G for n SimOT
+func (sender *SenderFmul) SenderInit(myGroup group.Group, a group.Scalar, n int) []group.Element {
+	sender.myGroup = myGroup
+	sender.a = a.Copy()
+	sender.deltas = make([]group.Scalar, n)
+	sender.m0s = make([][]byte, n)
+	sender.m1s = make([][]byte, n)
+	sender.simOTsenders = make([]simot.SenderSimOT, n)
+
+	var fmulWait sync.WaitGroup
+	fmulWait.Add(n)
+	for i := 0; i < n; i++ {
+		go func(index int) {
+			defer fmulWait.Done()
+			sender.deltas[index] = myGroup.RandomNonZeroScalar(rand.Reader)
+			m0iScalar := myGroup.NewScalar()
+			m0iScalar.Sub(sender.deltas[index], sender.a)
+
+			m0iByte, err := m0iScalar.MarshalBinary()
+			if err != nil {
+				panic(err)
+			}
+			sender.m0s[index] = m0iByte
+
+			m1iScalar := myGroup.NewScalar()
+			m1iScalar.Add(sender.deltas[index], sender.a)
+
+			m1iByte, err := m1iScalar.MarshalBinary()
+			if err != nil {
+				panic(err)
+			}
+			sender.m1s[index] = m1iByte
+
+			// n Sim OT Sender Initialization
+			var simOTSender simot.SenderSimOT
+			simOTSender.InitSender(myGroup, sender.m0s[index], sender.m1s[index], index)
+			sender.simOTsenders[index] = simOTSender
+		}(i)
+	}
+	fmulWait.Wait()
+
+	sender.s1 = myGroup.NewScalar()
+	sender.s1.SetUint64(0)
+
+	As := make([]group.Element, n)
+	for i := 0; i < n; i++ {
+		As[i] = sender.simOTsenders[i].A.Copy()
+	}
+	return As
+}
+
+// ---- Round1: Sender sends As to receiver ----
+
+// Receiver randomly generates n choice bits, either 0 or 1 for SimOT, either -1(Scalar) or 1(Scalar) for Fmul
+// Matching 0 or 1 to -1(Scalar) or 1(Scalar) in constant time
+// Input: myGroup, the group we operate in
+// Input: As, the n [ai]G received from sender
+// Input: b, the receiver private input
+// Input: n, the total number of SimOT
+// Output: Array of B = [b]G if c == 0, B = A+[b]G if c == 1
+func (receiver *ReceiverFmul) ReceiverRound1(myGroup group.Group, As []group.Element, b group.Scalar, n int) []group.Element {
+	receiver.myGroup = myGroup
+	receiver.b = b.Copy()
+	receiver.ts = make([]int, n)
+	receiver.tsScalar = make([]group.Scalar, n)
+	receiver.zs = make([]group.Scalar, n)
+	receiver.vs = make([]group.Scalar, n)
+
+	Scalar1 := myGroup.NewScalar()
+	Scalar1.SetUint64(1)
+	Scalar1.Neg(Scalar1)
+
+	receiver.simOTreceivers = make([]simot.ReceiverSimOT, n)
+
+	var fmulWait sync.WaitGroup
+	fmulWait.Add(n)
+	for i := 0; i < n; i++ {
+		go func(index int) {
+			defer fmulWait.Done()
+			currScalar := myGroup.NewScalar()
+			binaryBig, err := rand.Int(rand.Reader, big.NewInt(2))
+			if err != nil {
+				panic(err)
+			}
+			receiver.ts[index] = int(binaryBig.Int64())
+			currScalar.SetUint64(uint64(2 * receiver.ts[index]))
+			currScalar.Neg(currScalar)
+			receiver.tsScalar[index] = Scalar1.Copy()
+			receiver.tsScalar[index].Sub(receiver.tsScalar[index], currScalar)
+			receiver.zs[index] = myGroup.NewScalar()
+			receiver.simOTreceivers[index].Round1Receiver(myGroup, receiver.ts[index], index, As[index])
+		}(i)
+	}
+	fmulWait.Wait()
+
+	receiver.s2 = myGroup.NewScalar()
+	receiver.s2.SetUint64(0)
+
+	Bs := make([]group.Element, n)
+	for i := 0; i < n; i++ {
+		Bs[i] = receiver.simOTreceivers[i].B.Copy()
+	}
+	return Bs
+}
+
+// ---- Round 2: Receiver sends Bs = [bi]G or Ai+[bi]G to sender ----
+
+// Input: Bs, the n [bi]G or Ai+[bi]G received from receiver
+// Input: n, the total number of SimOT
+// Output: Array of m0s encryptions and m1s encryptions
+func (sender *SenderFmul) SenderRound2(Bs []group.Element, n int) ([][]byte, [][]byte) {
+	var fmulWait sync.WaitGroup
+	fmulWait.Add(n)
+	for i := 0; i < n; i++ {
+		go func(index int) {
+			defer fmulWait.Done()
+			sender.simOTsenders[index].Round2Sender(Bs[index])
+		}(i)
+	}
+	fmulWait.Wait()
+
+	e0s := make([][]byte, n)
+	e1s := make([][]byte, n)
+	for i := 0; i < n; i++ {
+		e0s[i], e1s[i] = sender.simOTsenders[i].Returne0e1()
+	}
+
+	return e0s, e1s
+}
+
+// ---- Round 3: Sender sends e0s, e1s to receiver ----
+
+// Input: e0s, e1s, the encryptions of m0s and m1s
+// Input: n, the total number of SimOT
+// Ouptut: Blinding sigma and Array of v
+func (receiver *ReceiverFmul) ReceiverRound3(e0s, e1s [][]byte, n int) (group.Scalar, []group.Scalar, error) {
+	var errGroup errgroup.Group
+	receiver.s2.SetUint64(0)
+
+	for i := 0; i < n; i++ {
+		func(index int) {
+			errGroup.Go(func() error {
+				errDec := receiver.simOTreceivers[index].Round3Receiver(e0s[index], e1s[index], receiver.ts[index])
+				if errDec != nil {
+					return errDec
+				}
+				mc := receiver.simOTreceivers[index].Returnmc()
+				errByte := receiver.zs[index].UnmarshalBinary(mc)
+				if errByte != nil {
+					panic(errByte)
+				}
+				return nil
+			})
+		}(i)
+	}
+
+	if err := errGroup.Wait(); err != nil {
+		return nil, nil, err
+	}
+
+	// v \times t = b
+	vn := receiver.b.Copy()
+	for i := 0; i < n-1; i++ {
+		receiver.vs[i] = receiver.myGroup.RandomNonZeroScalar(rand.Reader)
+		vt := receiver.myGroup.NewScalar()
+		vt.Mul(receiver.tsScalar[i], receiver.vs[i])
+		vn.Sub(vn, vt)
+	}
+	tsnInv := receiver.myGroup.NewScalar()
+	tsnInv.Inv(receiver.tsScalar[n-1])
+	vn.Mul(vn, tsnInv)
+	receiver.vs[n-1] = vn
+	receiver.sigma = receiver.myGroup.RandomNonZeroScalar(rand.Reader)
+
+	for i := 0; i < n; i++ {
+		vzi := receiver.myGroup.NewScalar()
+		vzi.Mul(receiver.vs[i], receiver.zs[i])
+		receiver.s2.Add(receiver.s2, vzi)
+	}
+
+	// s2 = v \times z + sigma
+	receiver.s2.Add(receiver.s2, receiver.sigma)
+
+	sigma := receiver.sigma.Copy()
+	vs := make([]group.Scalar, n)
+	for i := 0; i < n; i++ {
+		vs[i] = receiver.vs[i].Copy()
+	}
+
+	return sigma, vs, nil
+}
+
+// ---- Round 4: receiver sends sigma as well as vs to sender ----
+
+// Input: vs, from receiver
+// Input: sigma, blinding from receiver
+// Input: n, the total number of SimOT
+func (sender *SenderFmul) SenderRound4(vs []group.Scalar, sigma group.Scalar, n int) {
+	sender.s1.SetUint64(0)
+
+	vdelta := sender.myGroup.NewScalar()
+
+	// s1 = - v \times delta - sigma
+	for i := 0; i < n; i++ {
+		vdelta.Mul(vs[i], sender.deltas[i])
+		sender.s1.Sub(sender.s1, vdelta)
+	}
+	sender.s1.Sub(sender.s1, sigma)
+}
+
+func (sender *SenderFmul) Returns1() group.Scalar {
+	return sender.s1
+}
+
+func (receiver *ReceiverFmul) Returns2() group.Scalar {
+	return receiver.s2
+}
diff --git a/tss/ecdsa/dkls/fmul/fmulParty.go b/tss/ecdsa/dkls/fmul/fmulParty.go
new file mode 100644
index 00000000..44f312e5
--- /dev/null
+++ b/tss/ecdsa/dkls/fmul/fmulParty.go
@@ -0,0 +1,28 @@
+package fmul
+
+import (
+	"github.com/cloudflare/circl/group"
+	"github.com/cloudflare/circl/ot/simot"
+)
+
+type SenderFmul struct {
+	a            group.Scalar        // The input of the sender
+	deltas       []group.Scalar      // The n random of the sender
+	m0s          [][]byte            // The n m0 messages of the sender
+	m1s          [][]byte            // The n m1 messages of the sender
+	simOTsenders []simot.SenderSimOT // The n senders for n simOT
+	s1           group.Scalar        // The final additive share
+	myGroup      group.Group         // The elliptic curve we operate in
+}
+
+type ReceiverFmul struct {
+	b              group.Scalar          // The input of the receiver
+	ts             []int                 // The n choice bits of the receiver, either 0 or 1
+	tsScalar       []group.Scalar        // The scalar version of n choice bits, either -1 or 1
+	zs             []group.Scalar        // The n OT transferred messages from the sender
+	vs             []group.Scalar        // The n random of the receiver such that v*t = b
+	sigma          group.Scalar          // The blinding scalar
+	simOTreceivers []simot.ReceiverSimOT // The n receivers for n simOT
+	s2             group.Scalar          // The final additive share
+	myGroup        group.Group           // The elliptic curve we operate in
+}
diff --git a/tss/ecdsa/dkls/fmul/fmul_test.go b/tss/ecdsa/dkls/fmul/fmul_test.go
new file mode 100644
index 00000000..ca8ebefd
--- /dev/null
+++ b/tss/ecdsa/dkls/fmul/fmul_test.go
@@ -0,0 +1,214 @@
+// Reference: https://eprint.iacr.org/2021/1373.pdf
+// Sender and receiver has private input a and b
+// Sender and receiver get s1 and s2 such that a*b = s1+s2 from Fmul
+// This scheme based on pure OT but not OT extension
+
+package fmul
+
+import (
+	"crypto/rand"
+	"math/big"
+	"testing"
+
+	"github.com/cloudflare/circl/group"
+)
+
+const testFmulCount = 50
+
+// Input: aInput, bInput, the private input from both sender and receiver
+// Input: myGroup, the group we operate in
+// Input: n, the total number of SimOT
+func fmul(sender *SenderFmul, receiver *ReceiverFmul, aInput, bInput group.Scalar, myGroup group.Group, n int) error {
+	// Sender Initialization
+	As := sender.SenderInit(myGroup, aInput, n)
+
+	// ---- Round1: Sender sends As to receiver ----
+
+	Bs := receiver.ReceiverRound1(myGroup, As, bInput, n)
+
+	// ---- Round 2: Receiver sends Bs = [bi]G or Ai+[bi]G to sender ----
+
+	e0s, e1s := sender.SenderRound2(Bs, n)
+
+	// ---- Round 3: Sender sends e0s, e1s to receiver ----
+
+	sigma, vs, errDec := receiver.ReceiverRound3(e0s, e1s, n)
+	if errDec != nil {
+		return errDec
+	}
+
+	// ---- Round 4: receiver sends sigma as well as vs to sender ----
+
+	sender.SenderRound4(vs, sigma, n)
+
+	return nil
+}
+
+func testFmul(t *testing.T, myGroup group.Group) {
+	n := DecideNumOT(myGroup, 128)
+	var sender SenderFmul
+	var receiver ReceiverFmul
+	aSender := myGroup.RandomNonZeroScalar(rand.Reader)
+	bReceiver := myGroup.RandomNonZeroScalar(rand.Reader)
+
+	err := fmul(&sender, &receiver, aSender, bReceiver, myGroup, n)
+	if err != nil {
+		t.Error("Fmul decryption fail", err)
+	}
+
+	mul := myGroup.NewScalar()
+	add := myGroup.NewScalar()
+
+	add.Add(sender.s1, receiver.s2)
+	mul.Mul(aSender, bReceiver)
+
+	if add.IsEqual(mul) == false {
+		t.Error("Fmul reconstruction failed")
+	}
+}
+
+// Note the receiver has no space to cheat in the protocol.
+// The only way receiver can cheat is by making up incorrect vs which is the same as entering a different private input b
+// So we will only test the case where sender deviate from the protocol
+// Where sender exchanges one pair of e0 and e1.
+func testFmulNegative(t *testing.T, myGroup group.Group) {
+	n := DecideNumOT(myGroup, 128)
+	var sender SenderFmul
+	var receiver ReceiverFmul
+	aSender := myGroup.RandomNonZeroScalar(rand.Reader)
+	bReceiver := myGroup.RandomNonZeroScalar(rand.Reader)
+
+	// Sender Initialization
+	As := sender.SenderInit(myGroup, aSender, n)
+
+	// ---- Round1: Sender sends As to receiver ----
+
+	Bs := receiver.ReceiverRound1(myGroup, As, bReceiver, n)
+
+	// ---- Round 2: Receiver sends Bs = [bi]G or Ai+[bi]G to sender ----
+
+	e0s, e1s := sender.SenderRound2(Bs, n)
+
+	// exchange one pair of e0 and e1
+	nBig, err := rand.Int(rand.Reader, big.NewInt(int64(n)))
+	if err != nil {
+		panic(err)
+	}
+	randomIndex := int(nBig.Int64())
+	savee0 := make([]byte, len(e0s[randomIndex]))
+	copy(savee0, e0s[randomIndex])
+	e0s[randomIndex] = e1s[randomIndex]
+	e1s[randomIndex] = savee0
+
+	// ---- Round 3: Sender sends e0s, e1s to receiver ----
+
+	_, _, err = receiver.ReceiverRound3(e0s, e1s, n)
+	if err == nil {
+		t.Error("Fmul decryption should fail", err)
+	}
+}
+
+func benchmarFmul(b *testing.B, myGroup group.Group) {
+	n := DecideNumOT(myGroup, 128)
+	for iter := 0; iter < b.N; iter++ {
+		var sender SenderFmul
+		var receiver ReceiverFmul
+		aSender := myGroup.RandomNonZeroScalar(rand.Reader)
+		bReceiver := myGroup.RandomNonZeroScalar(rand.Reader)
+
+		err := fmul(&sender, &receiver, aSender, bReceiver, myGroup, n)
+		if err != nil {
+			b.Error("Fmul reconstruction failed")
+		}
+	}
+}
+
+func benchmarFmulRound(b *testing.B, myGroup group.Group) {
+	n := DecideNumOT(myGroup, 128)
+
+	var sender SenderFmul
+	var receiver ReceiverFmul
+	aSender := myGroup.RandomNonZeroScalar(rand.Reader)
+	bReceiver := myGroup.RandomNonZeroScalar(rand.Reader)
+
+	b.Run("Sender-Initialization", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			sender.SenderInit(myGroup, aSender, n)
+		}
+	})
+
+	As := sender.SenderInit(myGroup, aSender, n)
+
+	b.Run("Receiver-Round1", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			receiver.ReceiverRound1(myGroup, As, bReceiver, n)
+		}
+	})
+
+	Bs := receiver.ReceiverRound1(myGroup, As, bReceiver, n)
+
+	b.Run("Sender-Round2", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			sender.SenderRound2(Bs, n)
+		}
+	})
+
+	e0s, e1s := sender.SenderRound2(Bs, n)
+
+	b.Run("Receiver-Round3", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			_, _, err := receiver.ReceiverRound3(e0s, e1s, n)
+			if err != nil {
+				b.Error("Receiver-Round3 decryption failed")
+			}
+		}
+	})
+
+	sigma, vs, err := receiver.ReceiverRound3(e0s, e1s, n)
+	if err != nil {
+		b.Error("Receiver-Round3 decryption failed")
+	}
+
+	b.Run("Sender-Round4", func(b *testing.B) {
+		for i := 0; i < b.N; i++ {
+			sender.SenderRound4(vs, sigma, n)
+		}
+	})
+
+	sender.SenderRound4(vs, sigma, n)
+
+	add := myGroup.NewScalar()
+	mul := myGroup.NewScalar()
+
+	add.Add(sender.s1, receiver.s2)
+	mul.Mul(aSender, bReceiver)
+
+	if add.IsEqual(mul) == false {
+		b.Error("Fmul reconstruction failed")
+	}
+}
+
+func TestFmul(t *testing.T) {
+	t.Run("fmul", func(t *testing.T) {
+		for i := 0; i < testFmulCount; i++ {
+			currGroup := group.P256
+			testFmul(t, currGroup)
+		}
+	})
+	t.Run("fmulNegative", func(t *testing.T) {
+		for i := 0; i < testFmulCount; i++ {
+			currGroup := group.P256
+			testFmulNegative(t, currGroup)
+		}
+	})
+}
+
+func BenchmarkFmul(b *testing.B) {
+	currGroup := group.P256
+	benchmarFmul(b, currGroup)
+}
+
+func BenchmarkFmulRound(b *testing.B) {
+	currGroup := group.P256
+	benchmarFmulRound(b, currGroup)
+}
diff --git a/zk/dl/dl.go b/zk/dl/dl.go
new file mode 100644
index 00000000..98ac03d9
--- /dev/null
+++ b/zk/dl/dl.go
@@ -0,0 +1,86 @@
+// Reference: https://datatracker.ietf.org/doc/html/rfc8235#page-6
+// Prove the knowledge of [k] given [k]G, G and the curve where the points reside
+package dl
+
+import (
+	"io"
+
+	"github.com/cloudflare/circl/group"
+)
+
+// Input: myGroup, the group we operate in
+// Input: R = [kA]DB
+// Input: proverLabel, verifierLabel labels of prover and verifier
+// Ouptput: (V,r), the prove such that we know kA without revealing kA
+func ProveGen(myGroup group.Group, DB, R group.Element, kA group.Scalar, proverLabel, verifierLabel, dst []byte, rnd io.Reader) (group.Element, group.Scalar) {
+	v := myGroup.RandomNonZeroScalar(rnd)
+	V := myGroup.NewElement()
+	V.Mul(DB, v)
+
+	// Hash transcript (D_B | V | R | proverLabel | verifierLabel) to get the random coin
+	DBByte, errByte := DB.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	VByte, errByte := V.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+
+	RByte, errByte := R.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+
+	hashByte := append(DBByte, VByte...)
+	hashByte = append(hashByte, RByte...)
+	hashByte = append(hashByte, proverLabel...)
+	hashByte = append(hashByte, verifierLabel...)
+
+	c := myGroup.HashToScalar(hashByte, dst)
+
+	kAc := myGroup.NewScalar()
+	kAc.Mul(c, kA)
+	r := v.Copy()
+	r.Sub(r, kAc)
+
+	return V, r
+}
+
+// Input: myGroup, the group we operate in
+// Input: R = [kA]DB
+// Input: (V,r), the prove such that the prover knows kA
+// Input: proverLabel, verifierLabel labels of prover and verifier
+// Output: V ?= [r]D_B +[c]R
+func Verify(myGroup group.Group, DB, R group.Element, V group.Element, r group.Scalar, proverLabel, verifierLabel, dst []byte) bool {
+	// Hash the transcript (D_B | V | R | proverLabel | verifierLabel) to get the random coin
+	DBByte, errByte := DB.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	VByte, errByte := V.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+
+	RByte, errByte := R.MarshalBinary()
+	if errByte != nil {
+		panic(errByte)
+	}
+	hashByte := append(DBByte, VByte...)
+	hashByte = append(hashByte, RByte...)
+	hashByte = append(hashByte, proverLabel...)
+	hashByte = append(hashByte, verifierLabel...)
+
+	c := myGroup.HashToScalar(hashByte, dst)
+
+	rDB := myGroup.NewElement()
+	rDB.Mul(DB, r)
+
+	cR := myGroup.NewElement()
+	cR.Mul(R, c)
+
+	rDB.Add(rDB, cR)
+
+	return V.IsEqual(rDB)
+}
diff --git a/zk/dl/dl_test.go b/zk/dl/dl_test.go
new file mode 100644
index 00000000..aaf306e4
--- /dev/null
+++ b/zk/dl/dl_test.go
@@ -0,0 +1,59 @@
+package dl
+
+import (
+	"crypto/rand"
+	"testing"
+
+	"github.com/cloudflare/circl/group"
+)
+
+const testzkDLCount = 10
+
+func testzkDL(t *testing.T, myGroup group.Group) {
+	kA := myGroup.RandomNonZeroScalar(rand.Reader)
+	DB := myGroup.RandomElement(rand.Reader)
+
+	R := myGroup.NewElement()
+	R.Mul(DB, kA)
+
+	dst := "zeroknowledge"
+	rnd := rand.Reader
+	V, r := ProveGen(myGroup, DB, R, kA, []byte("Prover"), []byte("Verifier"), []byte(dst), rnd)
+
+	verify := Verify(myGroup, DB, R, V, r, []byte("Prover"), []byte("Verifier"), []byte(dst))
+	if verify == false {
+		t.Error("zkRDL verification failed")
+	}
+}
+
+func testzkDLNegative(t *testing.T, myGroup group.Group) {
+	kA := myGroup.RandomNonZeroScalar(rand.Reader)
+	DB := myGroup.RandomElement(rand.Reader)
+
+	R := myGroup.RandomElement(rand.Reader)
+
+	dst := "zeroknowledge"
+	rnd := rand.Reader
+	V, r := ProveGen(myGroup, DB, R, kA, []byte("Prover"), []byte("Verifier"), []byte(dst), rnd)
+
+	verify := Verify(myGroup, DB, R, V, r, []byte("Prover"), []byte("Verifier"), []byte(dst))
+	if verify == true {
+		t.Error("zkRDL verification should fail")
+	}
+}
+
+func TestZKDL(t *testing.T) {
+	t.Run("zkDL", func(t *testing.T) {
+		for i := 0; i < testzkDLCount; i++ {
+			currGroup := group.P256
+			testzkDL(t, currGroup)
+		}
+	})
+
+	t.Run("zkDLNegative", func(t *testing.T) {
+		for i := 0; i < testzkDLCount; i++ {
+			currGroup := group.P256
+			testzkDLNegative(t, currGroup)
+		}
+	})
+}